computed radiography. objectives historical perspectives of computerized imaging s/f vs cr vs ddr...
TRANSCRIPT
![Page 1: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/1.jpg)
Computed Radiography
Objectives
Historical perspectives of computerized imaging
SF vs CR vs DDR imaging Basics of CR image capture CR imaging equipment Advantages of CR imaging Radiation Protection
Digital Imaging
bull Image acquisition that produces an electronic image that can be viewed and manipulated on a computer
bull Analog-to-digital converters
Development of Digital Imaging
bull The second major milestone in medical imaging the invention of CT
bull Began the coupling of the computers and imaging
bull Godfrey Hounsfield in the 1970rsquos
First-generation CT unit dedicated head scanner
(Photograph taken at Roentgen Museum Lennep Germany)
Digital Imaging Techniques
Are used inComputed TomographyMagnetic Resonance ImagingDiagnostic UltrasoundComputerized RadiographyDigital RadiographyDigital Fluoroscopy
CR amp DR imaging
Was limited until sufficient computer technology became available to process the large quantities of data generated
Clinical use began in the 1980rsquos (CR)
1990rsquos (DDR)
Methods to Digitize an Imagebull 1 Film Digitizer - Teleradiography system
(PACS DICOM)
bull 2 Video Camera (vidicon or plumbicon)
bull 3 Computed Radiography
bull 4 Direct Radiography
Computed Radiography Terms
PSL = photostimulable luminescence PSP = photostimulable phosphor SPS = storage phosphor screen IP = imaging plate SP = storage phosphor PMT = photomultiplier tube PD = photodiode SF = screen-film
Computed Radiography
Fundamentals of
Computerized Radiography
CR IR
Cassette-based digital radiography
In SF the intensifying screens contain phosphor that emits light in response to x-ray interaction
In CR the response to x-ray interaction is trapped photon energy (e-) on the PSP plate
Conventional radiography latent image formation
CR latent image formation
What Is Digital ImagingDigital imaging is the acquisition of
images to a computer rather than directly to film
15
IMAGE CREATION
SAME RADIOGRAPHY EQUIPMENT USED
THE DIFFERENCE IS HOW IT IS CAPTURED
STORED VIEWED And POST -PROCESSED
General Overview CR
PSP cassette exposed by conventional x-ray equipment
Latent image generated as a matrix of trapped electrons in the PSP plate
CR BASICS
bull Eliminates the need for film as a recording storage amp viewing medium
bull PSP Plate ndash receiverbull Archive Manager ndash storagebull Monitor - Viewing
Digital
Radiography
DirectCapture
IndirectCapture
Direct-to-DigitalRadiography
(DDR)-Selenium
ComputedRadiography
(CR) - PSL
LaserScanningDigitizers
Direct-to-DigitalRadiographySilicon Scint
DDR CR
CR SYSTEM COMPONENTS
CASSETTES (phosphor plates) ID STATION IMAGE PREVIEW (QC)
STATION DIGITIZER VIEWING STATION
ID STATIONID STATION
CR Readers
AKA
CR Processors
Fuji Agfa Kodak
Computed Radiographic Readers
CR ndash PSP plate
photostimulable phosphor (PSP) plate
Exit photons energizes the PSP plate
The energy is stored in traps on plate (latent image)
PLATE scanned in CR READER
Imaging Plate (IP)
Contained in a cassette
Handled the same as SF cassettes
Processed more like daylight processor with no chemicals
IP has lead backing to reduce scatter
Imaging Plate Construction
A thin sheet of plastic
IPrsquos have several layersA protective layer This is a very thin tough
clear plastic that protects the phosphor layer A phosphor or active layer This is a layer of
photostimulable phosphor that ldquotrapsrdquo electrons during exposure
Active Layer - Crystals The materials that make up the PSP plate
are from the barium fluorohalide family
Barium fluorohalide chlorohalide or bromohalide crystals The most common crystal uses is barium fluorohalide with europium
Acquiring the Image
The remnant beam interacts with electrons in the barium fluorohalide crystals
This interaction stimulates or gives energy to electrons in the crystals allowing them to enter the conductive layer
The Conductuve layer is where they are
trapped in an area of the crystal known as the color or phosphor center
Acquiring the Image cont
This trapped signal will remain for hours even days although deterioration begins almost immediately IR should be processed as soon as possible
The trapped signal is never completely lost
Imaging Plate Construction
A reflective layer This is a layer that sends light in a forward direction when released in the cassette reader This layer may be black to reduce the spread of stimulating light and the escape of emitted light Some detail is lost in this process
Imaging Plate Construction Conductive layer This is a layer of material that
absorbs and reduces static electricity A color layer Newer plates may contain a color
layer located between the active layer and the support that absorbs the stimulating light but reflects emitted light
A support layer This is a semirigid material that gives the imaging sheet some strength
A backing layer This is a soft polymer that protects the back of the cassette
Cross section of a PSP screen
Needle PSP increase the absorption of x-rays and limit the spread of light emission
IP Design
Designed to optimize the intensity of light release (CE)
Enhance the absorption of x-rays (DQE)
Limit the spread of light emission for more detail
Photostimulable Luminescence When the cassette is put into the reader the
imaging plate is extracted and scanned With a helium laser beam or in more recent
systems solid-state laser diodes This beam about 100μm wide with a wavelength
of 633 nm (or 670 to 690 nm for solid state) Scans the plate with red light in a raster pattern
and gives energy to the trapped electrons
X-ray interaction with a PSP screen
1
2
X-ray interactions with the screen phosphors causes an e- to excited
When e- return to groundstate visible light is emitted
CR Phosphor PlatesCR Phosphor Plates
ABSORPTION EMISSION
X-RAY
LIGHT
LASER STIMULATION
ELECTRONTRAP
ELECTRONTRAP
CR Reader ndash PSP plate
Stimulates the matrix of trapped E- by a RED OR ULTRAVIOLET laser light
Trapped E- energy is released in a form of VIOLETBLUE light
Violet light is captured by PMT ndash is amplified and converted into a digital signal
Sequence of CR imaging
PMT
Beam deflector
LaserSource
Light channeling guide
Plate translation Sub-scan direction
Laser beam Scan direction
Output Signal
Reference detec tor
Beam splitter
Cylindrical m irrorf-thetalens
Amplifier
ADC
To imageprocessor
How CR works
Released light is captured by a PMT (photo
multiplier tube) An ultrasensitive photomultiplier tube or CCD (charged couple device)
PSP light is amplified by the PMT or CCD
This light is sent to the analog to digital converter (ADC) To convert light to binary
PMT (photomultiplier tube) The intensity (brightness) of the light ndash
correlates to the density on the image
So lots of light will correlate to what size number amp what color on the image
The digital numeric values are stored in matrix form called pixels for display on a cathode ray tube (CRT) or printed on film
ERASING THE SCREEN ~50 of trapped electrons released during ldquoreadrdquo After image is recorded Plate is erased with high intensity white light and
re-used Erasing should be done after every exposure or
at minimum every 24 hours to avoid ghosting on future images
Basics of Digital Images
bull digital images are a (matrix) of pixel (picture element) values
Pixels Digital images are made of discrete picture
elements arranged in a matrix The size of the image is described in the binary number system
Modern imaging systems are at least 1024 x 1024
4096 x 4096 is being developed for digital radiography
Matrix = each cell corresponds to a specific location on the image
Pixel
Pixels
Digital Images ndash Bit Depth
bull Pixel values can be any bit depth (values from 0 to 1023)
bull Bit depth = or gray shades available for image display
bull Image contrast can be manipulated to stretched or contracted to alter the displayed contrast
bull Typically use ldquowindow widthrdquo and ldquowindow levelrdquo to alter displayed contrast and brightness
Digital - Grayscale
Bit depth Number of gray shades
available for display 8 bit 256 10 bit 1024 12 bit 4096 4 bit 16384
Display Bit Depth1 bit 6 bit 8 bit
2 shades 64 shades 256 shades
Computed Radiography As the plate is scanned ldquoreadrdquo data is collected
at a specific frequency = Sampling frequency
Spatial resolution determined by sampling frequency
With some systems the smaller IRrsquos have higher sampling frequencies amp more pixels per mm = more spatial resolution
Signal Loss (reducing image quality) Signal-to-Noise Ratio
Principle source of noise on the image is scatter radiation
Scattering of emitted light off screen
The efficiency of the photomultiplier tubes (PMTs) and photodiodes (PDs)
Improving Signal-to-Noise Ratio
Optical filter is used to prevent the longer-wavelength laser light affecting the image formation
Increasing exposure to IR Newer CR systems are better at reducing noise at lower exposure levels
Technique Selections
What are some factors that technologist must take into consideration when selecting a technique
What regulates that technologists to select appropriate techniques in FS CR amp DR
Screen Film
Self regulating system The receptor speed and film HampD curve defined
the proper exposure Achieving optimal OD guaranteed appropriate
exposure to the patient Over exposed = dark image Correct exposure = correct OD Under exposed = light image
Characteristic curveof radiographic film
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 2: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/2.jpg)
Objectives
Historical perspectives of computerized imaging
SF vs CR vs DDR imaging Basics of CR image capture CR imaging equipment Advantages of CR imaging Radiation Protection
Digital Imaging
bull Image acquisition that produces an electronic image that can be viewed and manipulated on a computer
bull Analog-to-digital converters
Development of Digital Imaging
bull The second major milestone in medical imaging the invention of CT
bull Began the coupling of the computers and imaging
bull Godfrey Hounsfield in the 1970rsquos
First-generation CT unit dedicated head scanner
(Photograph taken at Roentgen Museum Lennep Germany)
Digital Imaging Techniques
Are used inComputed TomographyMagnetic Resonance ImagingDiagnostic UltrasoundComputerized RadiographyDigital RadiographyDigital Fluoroscopy
CR amp DR imaging
Was limited until sufficient computer technology became available to process the large quantities of data generated
Clinical use began in the 1980rsquos (CR)
1990rsquos (DDR)
Methods to Digitize an Imagebull 1 Film Digitizer - Teleradiography system
(PACS DICOM)
bull 2 Video Camera (vidicon or plumbicon)
bull 3 Computed Radiography
bull 4 Direct Radiography
Computed Radiography Terms
PSL = photostimulable luminescence PSP = photostimulable phosphor SPS = storage phosphor screen IP = imaging plate SP = storage phosphor PMT = photomultiplier tube PD = photodiode SF = screen-film
Computed Radiography
Fundamentals of
Computerized Radiography
CR IR
Cassette-based digital radiography
In SF the intensifying screens contain phosphor that emits light in response to x-ray interaction
In CR the response to x-ray interaction is trapped photon energy (e-) on the PSP plate
Conventional radiography latent image formation
CR latent image formation
What Is Digital ImagingDigital imaging is the acquisition of
images to a computer rather than directly to film
15
IMAGE CREATION
SAME RADIOGRAPHY EQUIPMENT USED
THE DIFFERENCE IS HOW IT IS CAPTURED
STORED VIEWED And POST -PROCESSED
General Overview CR
PSP cassette exposed by conventional x-ray equipment
Latent image generated as a matrix of trapped electrons in the PSP plate
CR BASICS
bull Eliminates the need for film as a recording storage amp viewing medium
bull PSP Plate ndash receiverbull Archive Manager ndash storagebull Monitor - Viewing
Digital
Radiography
DirectCapture
IndirectCapture
Direct-to-DigitalRadiography
(DDR)-Selenium
ComputedRadiography
(CR) - PSL
LaserScanningDigitizers
Direct-to-DigitalRadiographySilicon Scint
DDR CR
CR SYSTEM COMPONENTS
CASSETTES (phosphor plates) ID STATION IMAGE PREVIEW (QC)
STATION DIGITIZER VIEWING STATION
ID STATIONID STATION
CR Readers
AKA
CR Processors
Fuji Agfa Kodak
Computed Radiographic Readers
CR ndash PSP plate
photostimulable phosphor (PSP) plate
Exit photons energizes the PSP plate
The energy is stored in traps on plate (latent image)
PLATE scanned in CR READER
Imaging Plate (IP)
Contained in a cassette
Handled the same as SF cassettes
Processed more like daylight processor with no chemicals
IP has lead backing to reduce scatter
Imaging Plate Construction
A thin sheet of plastic
IPrsquos have several layersA protective layer This is a very thin tough
clear plastic that protects the phosphor layer A phosphor or active layer This is a layer of
photostimulable phosphor that ldquotrapsrdquo electrons during exposure
Active Layer - Crystals The materials that make up the PSP plate
are from the barium fluorohalide family
Barium fluorohalide chlorohalide or bromohalide crystals The most common crystal uses is barium fluorohalide with europium
Acquiring the Image
The remnant beam interacts with electrons in the barium fluorohalide crystals
This interaction stimulates or gives energy to electrons in the crystals allowing them to enter the conductive layer
The Conductuve layer is where they are
trapped in an area of the crystal known as the color or phosphor center
Acquiring the Image cont
This trapped signal will remain for hours even days although deterioration begins almost immediately IR should be processed as soon as possible
The trapped signal is never completely lost
Imaging Plate Construction
A reflective layer This is a layer that sends light in a forward direction when released in the cassette reader This layer may be black to reduce the spread of stimulating light and the escape of emitted light Some detail is lost in this process
Imaging Plate Construction Conductive layer This is a layer of material that
absorbs and reduces static electricity A color layer Newer plates may contain a color
layer located between the active layer and the support that absorbs the stimulating light but reflects emitted light
A support layer This is a semirigid material that gives the imaging sheet some strength
A backing layer This is a soft polymer that protects the back of the cassette
Cross section of a PSP screen
Needle PSP increase the absorption of x-rays and limit the spread of light emission
IP Design
Designed to optimize the intensity of light release (CE)
Enhance the absorption of x-rays (DQE)
Limit the spread of light emission for more detail
Photostimulable Luminescence When the cassette is put into the reader the
imaging plate is extracted and scanned With a helium laser beam or in more recent
systems solid-state laser diodes This beam about 100μm wide with a wavelength
of 633 nm (or 670 to 690 nm for solid state) Scans the plate with red light in a raster pattern
and gives energy to the trapped electrons
X-ray interaction with a PSP screen
1
2
X-ray interactions with the screen phosphors causes an e- to excited
When e- return to groundstate visible light is emitted
CR Phosphor PlatesCR Phosphor Plates
ABSORPTION EMISSION
X-RAY
LIGHT
LASER STIMULATION
ELECTRONTRAP
ELECTRONTRAP
CR Reader ndash PSP plate
Stimulates the matrix of trapped E- by a RED OR ULTRAVIOLET laser light
Trapped E- energy is released in a form of VIOLETBLUE light
Violet light is captured by PMT ndash is amplified and converted into a digital signal
Sequence of CR imaging
PMT
Beam deflector
LaserSource
Light channeling guide
Plate translation Sub-scan direction
Laser beam Scan direction
Output Signal
Reference detec tor
Beam splitter
Cylindrical m irrorf-thetalens
Amplifier
ADC
To imageprocessor
How CR works
Released light is captured by a PMT (photo
multiplier tube) An ultrasensitive photomultiplier tube or CCD (charged couple device)
PSP light is amplified by the PMT or CCD
This light is sent to the analog to digital converter (ADC) To convert light to binary
PMT (photomultiplier tube) The intensity (brightness) of the light ndash
correlates to the density on the image
So lots of light will correlate to what size number amp what color on the image
The digital numeric values are stored in matrix form called pixels for display on a cathode ray tube (CRT) or printed on film
ERASING THE SCREEN ~50 of trapped electrons released during ldquoreadrdquo After image is recorded Plate is erased with high intensity white light and
re-used Erasing should be done after every exposure or
at minimum every 24 hours to avoid ghosting on future images
Basics of Digital Images
bull digital images are a (matrix) of pixel (picture element) values
Pixels Digital images are made of discrete picture
elements arranged in a matrix The size of the image is described in the binary number system
Modern imaging systems are at least 1024 x 1024
4096 x 4096 is being developed for digital radiography
Matrix = each cell corresponds to a specific location on the image
Pixel
Pixels
Digital Images ndash Bit Depth
bull Pixel values can be any bit depth (values from 0 to 1023)
bull Bit depth = or gray shades available for image display
bull Image contrast can be manipulated to stretched or contracted to alter the displayed contrast
bull Typically use ldquowindow widthrdquo and ldquowindow levelrdquo to alter displayed contrast and brightness
Digital - Grayscale
Bit depth Number of gray shades
available for display 8 bit 256 10 bit 1024 12 bit 4096 4 bit 16384
Display Bit Depth1 bit 6 bit 8 bit
2 shades 64 shades 256 shades
Computed Radiography As the plate is scanned ldquoreadrdquo data is collected
at a specific frequency = Sampling frequency
Spatial resolution determined by sampling frequency
With some systems the smaller IRrsquos have higher sampling frequencies amp more pixels per mm = more spatial resolution
Signal Loss (reducing image quality) Signal-to-Noise Ratio
Principle source of noise on the image is scatter radiation
Scattering of emitted light off screen
The efficiency of the photomultiplier tubes (PMTs) and photodiodes (PDs)
Improving Signal-to-Noise Ratio
Optical filter is used to prevent the longer-wavelength laser light affecting the image formation
Increasing exposure to IR Newer CR systems are better at reducing noise at lower exposure levels
Technique Selections
What are some factors that technologist must take into consideration when selecting a technique
What regulates that technologists to select appropriate techniques in FS CR amp DR
Screen Film
Self regulating system The receptor speed and film HampD curve defined
the proper exposure Achieving optimal OD guaranteed appropriate
exposure to the patient Over exposed = dark image Correct exposure = correct OD Under exposed = light image
Characteristic curveof radiographic film
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 3: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/3.jpg)
Digital Imaging
bull Image acquisition that produces an electronic image that can be viewed and manipulated on a computer
bull Analog-to-digital converters
Development of Digital Imaging
bull The second major milestone in medical imaging the invention of CT
bull Began the coupling of the computers and imaging
bull Godfrey Hounsfield in the 1970rsquos
First-generation CT unit dedicated head scanner
(Photograph taken at Roentgen Museum Lennep Germany)
Digital Imaging Techniques
Are used inComputed TomographyMagnetic Resonance ImagingDiagnostic UltrasoundComputerized RadiographyDigital RadiographyDigital Fluoroscopy
CR amp DR imaging
Was limited until sufficient computer technology became available to process the large quantities of data generated
Clinical use began in the 1980rsquos (CR)
1990rsquos (DDR)
Methods to Digitize an Imagebull 1 Film Digitizer - Teleradiography system
(PACS DICOM)
bull 2 Video Camera (vidicon or plumbicon)
bull 3 Computed Radiography
bull 4 Direct Radiography
Computed Radiography Terms
PSL = photostimulable luminescence PSP = photostimulable phosphor SPS = storage phosphor screen IP = imaging plate SP = storage phosphor PMT = photomultiplier tube PD = photodiode SF = screen-film
Computed Radiography
Fundamentals of
Computerized Radiography
CR IR
Cassette-based digital radiography
In SF the intensifying screens contain phosphor that emits light in response to x-ray interaction
In CR the response to x-ray interaction is trapped photon energy (e-) on the PSP plate
Conventional radiography latent image formation
CR latent image formation
What Is Digital ImagingDigital imaging is the acquisition of
images to a computer rather than directly to film
15
IMAGE CREATION
SAME RADIOGRAPHY EQUIPMENT USED
THE DIFFERENCE IS HOW IT IS CAPTURED
STORED VIEWED And POST -PROCESSED
General Overview CR
PSP cassette exposed by conventional x-ray equipment
Latent image generated as a matrix of trapped electrons in the PSP plate
CR BASICS
bull Eliminates the need for film as a recording storage amp viewing medium
bull PSP Plate ndash receiverbull Archive Manager ndash storagebull Monitor - Viewing
Digital
Radiography
DirectCapture
IndirectCapture
Direct-to-DigitalRadiography
(DDR)-Selenium
ComputedRadiography
(CR) - PSL
LaserScanningDigitizers
Direct-to-DigitalRadiographySilicon Scint
DDR CR
CR SYSTEM COMPONENTS
CASSETTES (phosphor plates) ID STATION IMAGE PREVIEW (QC)
STATION DIGITIZER VIEWING STATION
ID STATIONID STATION
CR Readers
AKA
CR Processors
Fuji Agfa Kodak
Computed Radiographic Readers
CR ndash PSP plate
photostimulable phosphor (PSP) plate
Exit photons energizes the PSP plate
The energy is stored in traps on plate (latent image)
PLATE scanned in CR READER
Imaging Plate (IP)
Contained in a cassette
Handled the same as SF cassettes
Processed more like daylight processor with no chemicals
IP has lead backing to reduce scatter
Imaging Plate Construction
A thin sheet of plastic
IPrsquos have several layersA protective layer This is a very thin tough
clear plastic that protects the phosphor layer A phosphor or active layer This is a layer of
photostimulable phosphor that ldquotrapsrdquo electrons during exposure
Active Layer - Crystals The materials that make up the PSP plate
are from the barium fluorohalide family
Barium fluorohalide chlorohalide or bromohalide crystals The most common crystal uses is barium fluorohalide with europium
Acquiring the Image
The remnant beam interacts with electrons in the barium fluorohalide crystals
This interaction stimulates or gives energy to electrons in the crystals allowing them to enter the conductive layer
The Conductuve layer is where they are
trapped in an area of the crystal known as the color or phosphor center
Acquiring the Image cont
This trapped signal will remain for hours even days although deterioration begins almost immediately IR should be processed as soon as possible
The trapped signal is never completely lost
Imaging Plate Construction
A reflective layer This is a layer that sends light in a forward direction when released in the cassette reader This layer may be black to reduce the spread of stimulating light and the escape of emitted light Some detail is lost in this process
Imaging Plate Construction Conductive layer This is a layer of material that
absorbs and reduces static electricity A color layer Newer plates may contain a color
layer located between the active layer and the support that absorbs the stimulating light but reflects emitted light
A support layer This is a semirigid material that gives the imaging sheet some strength
A backing layer This is a soft polymer that protects the back of the cassette
Cross section of a PSP screen
Needle PSP increase the absorption of x-rays and limit the spread of light emission
IP Design
Designed to optimize the intensity of light release (CE)
Enhance the absorption of x-rays (DQE)
Limit the spread of light emission for more detail
Photostimulable Luminescence When the cassette is put into the reader the
imaging plate is extracted and scanned With a helium laser beam or in more recent
systems solid-state laser diodes This beam about 100μm wide with a wavelength
of 633 nm (or 670 to 690 nm for solid state) Scans the plate with red light in a raster pattern
and gives energy to the trapped electrons
X-ray interaction with a PSP screen
1
2
X-ray interactions with the screen phosphors causes an e- to excited
When e- return to groundstate visible light is emitted
CR Phosphor PlatesCR Phosphor Plates
ABSORPTION EMISSION
X-RAY
LIGHT
LASER STIMULATION
ELECTRONTRAP
ELECTRONTRAP
CR Reader ndash PSP plate
Stimulates the matrix of trapped E- by a RED OR ULTRAVIOLET laser light
Trapped E- energy is released in a form of VIOLETBLUE light
Violet light is captured by PMT ndash is amplified and converted into a digital signal
Sequence of CR imaging
PMT
Beam deflector
LaserSource
Light channeling guide
Plate translation Sub-scan direction
Laser beam Scan direction
Output Signal
Reference detec tor
Beam splitter
Cylindrical m irrorf-thetalens
Amplifier
ADC
To imageprocessor
How CR works
Released light is captured by a PMT (photo
multiplier tube) An ultrasensitive photomultiplier tube or CCD (charged couple device)
PSP light is amplified by the PMT or CCD
This light is sent to the analog to digital converter (ADC) To convert light to binary
PMT (photomultiplier tube) The intensity (brightness) of the light ndash
correlates to the density on the image
So lots of light will correlate to what size number amp what color on the image
The digital numeric values are stored in matrix form called pixels for display on a cathode ray tube (CRT) or printed on film
ERASING THE SCREEN ~50 of trapped electrons released during ldquoreadrdquo After image is recorded Plate is erased with high intensity white light and
re-used Erasing should be done after every exposure or
at minimum every 24 hours to avoid ghosting on future images
Basics of Digital Images
bull digital images are a (matrix) of pixel (picture element) values
Pixels Digital images are made of discrete picture
elements arranged in a matrix The size of the image is described in the binary number system
Modern imaging systems are at least 1024 x 1024
4096 x 4096 is being developed for digital radiography
Matrix = each cell corresponds to a specific location on the image
Pixel
Pixels
Digital Images ndash Bit Depth
bull Pixel values can be any bit depth (values from 0 to 1023)
bull Bit depth = or gray shades available for image display
bull Image contrast can be manipulated to stretched or contracted to alter the displayed contrast
bull Typically use ldquowindow widthrdquo and ldquowindow levelrdquo to alter displayed contrast and brightness
Digital - Grayscale
Bit depth Number of gray shades
available for display 8 bit 256 10 bit 1024 12 bit 4096 4 bit 16384
Display Bit Depth1 bit 6 bit 8 bit
2 shades 64 shades 256 shades
Computed Radiography As the plate is scanned ldquoreadrdquo data is collected
at a specific frequency = Sampling frequency
Spatial resolution determined by sampling frequency
With some systems the smaller IRrsquos have higher sampling frequencies amp more pixels per mm = more spatial resolution
Signal Loss (reducing image quality) Signal-to-Noise Ratio
Principle source of noise on the image is scatter radiation
Scattering of emitted light off screen
The efficiency of the photomultiplier tubes (PMTs) and photodiodes (PDs)
Improving Signal-to-Noise Ratio
Optical filter is used to prevent the longer-wavelength laser light affecting the image formation
Increasing exposure to IR Newer CR systems are better at reducing noise at lower exposure levels
Technique Selections
What are some factors that technologist must take into consideration when selecting a technique
What regulates that technologists to select appropriate techniques in FS CR amp DR
Screen Film
Self regulating system The receptor speed and film HampD curve defined
the proper exposure Achieving optimal OD guaranteed appropriate
exposure to the patient Over exposed = dark image Correct exposure = correct OD Under exposed = light image
Characteristic curveof radiographic film
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 4: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/4.jpg)
Development of Digital Imaging
bull The second major milestone in medical imaging the invention of CT
bull Began the coupling of the computers and imaging
bull Godfrey Hounsfield in the 1970rsquos
First-generation CT unit dedicated head scanner
(Photograph taken at Roentgen Museum Lennep Germany)
Digital Imaging Techniques
Are used inComputed TomographyMagnetic Resonance ImagingDiagnostic UltrasoundComputerized RadiographyDigital RadiographyDigital Fluoroscopy
CR amp DR imaging
Was limited until sufficient computer technology became available to process the large quantities of data generated
Clinical use began in the 1980rsquos (CR)
1990rsquos (DDR)
Methods to Digitize an Imagebull 1 Film Digitizer - Teleradiography system
(PACS DICOM)
bull 2 Video Camera (vidicon or plumbicon)
bull 3 Computed Radiography
bull 4 Direct Radiography
Computed Radiography Terms
PSL = photostimulable luminescence PSP = photostimulable phosphor SPS = storage phosphor screen IP = imaging plate SP = storage phosphor PMT = photomultiplier tube PD = photodiode SF = screen-film
Computed Radiography
Fundamentals of
Computerized Radiography
CR IR
Cassette-based digital radiography
In SF the intensifying screens contain phosphor that emits light in response to x-ray interaction
In CR the response to x-ray interaction is trapped photon energy (e-) on the PSP plate
Conventional radiography latent image formation
CR latent image formation
What Is Digital ImagingDigital imaging is the acquisition of
images to a computer rather than directly to film
15
IMAGE CREATION
SAME RADIOGRAPHY EQUIPMENT USED
THE DIFFERENCE IS HOW IT IS CAPTURED
STORED VIEWED And POST -PROCESSED
General Overview CR
PSP cassette exposed by conventional x-ray equipment
Latent image generated as a matrix of trapped electrons in the PSP plate
CR BASICS
bull Eliminates the need for film as a recording storage amp viewing medium
bull PSP Plate ndash receiverbull Archive Manager ndash storagebull Monitor - Viewing
Digital
Radiography
DirectCapture
IndirectCapture
Direct-to-DigitalRadiography
(DDR)-Selenium
ComputedRadiography
(CR) - PSL
LaserScanningDigitizers
Direct-to-DigitalRadiographySilicon Scint
DDR CR
CR SYSTEM COMPONENTS
CASSETTES (phosphor plates) ID STATION IMAGE PREVIEW (QC)
STATION DIGITIZER VIEWING STATION
ID STATIONID STATION
CR Readers
AKA
CR Processors
Fuji Agfa Kodak
Computed Radiographic Readers
CR ndash PSP plate
photostimulable phosphor (PSP) plate
Exit photons energizes the PSP plate
The energy is stored in traps on plate (latent image)
PLATE scanned in CR READER
Imaging Plate (IP)
Contained in a cassette
Handled the same as SF cassettes
Processed more like daylight processor with no chemicals
IP has lead backing to reduce scatter
Imaging Plate Construction
A thin sheet of plastic
IPrsquos have several layersA protective layer This is a very thin tough
clear plastic that protects the phosphor layer A phosphor or active layer This is a layer of
photostimulable phosphor that ldquotrapsrdquo electrons during exposure
Active Layer - Crystals The materials that make up the PSP plate
are from the barium fluorohalide family
Barium fluorohalide chlorohalide or bromohalide crystals The most common crystal uses is barium fluorohalide with europium
Acquiring the Image
The remnant beam interacts with electrons in the barium fluorohalide crystals
This interaction stimulates or gives energy to electrons in the crystals allowing them to enter the conductive layer
The Conductuve layer is where they are
trapped in an area of the crystal known as the color or phosphor center
Acquiring the Image cont
This trapped signal will remain for hours even days although deterioration begins almost immediately IR should be processed as soon as possible
The trapped signal is never completely lost
Imaging Plate Construction
A reflective layer This is a layer that sends light in a forward direction when released in the cassette reader This layer may be black to reduce the spread of stimulating light and the escape of emitted light Some detail is lost in this process
Imaging Plate Construction Conductive layer This is a layer of material that
absorbs and reduces static electricity A color layer Newer plates may contain a color
layer located between the active layer and the support that absorbs the stimulating light but reflects emitted light
A support layer This is a semirigid material that gives the imaging sheet some strength
A backing layer This is a soft polymer that protects the back of the cassette
Cross section of a PSP screen
Needle PSP increase the absorption of x-rays and limit the spread of light emission
IP Design
Designed to optimize the intensity of light release (CE)
Enhance the absorption of x-rays (DQE)
Limit the spread of light emission for more detail
Photostimulable Luminescence When the cassette is put into the reader the
imaging plate is extracted and scanned With a helium laser beam or in more recent
systems solid-state laser diodes This beam about 100μm wide with a wavelength
of 633 nm (or 670 to 690 nm for solid state) Scans the plate with red light in a raster pattern
and gives energy to the trapped electrons
X-ray interaction with a PSP screen
1
2
X-ray interactions with the screen phosphors causes an e- to excited
When e- return to groundstate visible light is emitted
CR Phosphor PlatesCR Phosphor Plates
ABSORPTION EMISSION
X-RAY
LIGHT
LASER STIMULATION
ELECTRONTRAP
ELECTRONTRAP
CR Reader ndash PSP plate
Stimulates the matrix of trapped E- by a RED OR ULTRAVIOLET laser light
Trapped E- energy is released in a form of VIOLETBLUE light
Violet light is captured by PMT ndash is amplified and converted into a digital signal
Sequence of CR imaging
PMT
Beam deflector
LaserSource
Light channeling guide
Plate translation Sub-scan direction
Laser beam Scan direction
Output Signal
Reference detec tor
Beam splitter
Cylindrical m irrorf-thetalens
Amplifier
ADC
To imageprocessor
How CR works
Released light is captured by a PMT (photo
multiplier tube) An ultrasensitive photomultiplier tube or CCD (charged couple device)
PSP light is amplified by the PMT or CCD
This light is sent to the analog to digital converter (ADC) To convert light to binary
PMT (photomultiplier tube) The intensity (brightness) of the light ndash
correlates to the density on the image
So lots of light will correlate to what size number amp what color on the image
The digital numeric values are stored in matrix form called pixels for display on a cathode ray tube (CRT) or printed on film
ERASING THE SCREEN ~50 of trapped electrons released during ldquoreadrdquo After image is recorded Plate is erased with high intensity white light and
re-used Erasing should be done after every exposure or
at minimum every 24 hours to avoid ghosting on future images
Basics of Digital Images
bull digital images are a (matrix) of pixel (picture element) values
Pixels Digital images are made of discrete picture
elements arranged in a matrix The size of the image is described in the binary number system
Modern imaging systems are at least 1024 x 1024
4096 x 4096 is being developed for digital radiography
Matrix = each cell corresponds to a specific location on the image
Pixel
Pixels
Digital Images ndash Bit Depth
bull Pixel values can be any bit depth (values from 0 to 1023)
bull Bit depth = or gray shades available for image display
bull Image contrast can be manipulated to stretched or contracted to alter the displayed contrast
bull Typically use ldquowindow widthrdquo and ldquowindow levelrdquo to alter displayed contrast and brightness
Digital - Grayscale
Bit depth Number of gray shades
available for display 8 bit 256 10 bit 1024 12 bit 4096 4 bit 16384
Display Bit Depth1 bit 6 bit 8 bit
2 shades 64 shades 256 shades
Computed Radiography As the plate is scanned ldquoreadrdquo data is collected
at a specific frequency = Sampling frequency
Spatial resolution determined by sampling frequency
With some systems the smaller IRrsquos have higher sampling frequencies amp more pixels per mm = more spatial resolution
Signal Loss (reducing image quality) Signal-to-Noise Ratio
Principle source of noise on the image is scatter radiation
Scattering of emitted light off screen
The efficiency of the photomultiplier tubes (PMTs) and photodiodes (PDs)
Improving Signal-to-Noise Ratio
Optical filter is used to prevent the longer-wavelength laser light affecting the image formation
Increasing exposure to IR Newer CR systems are better at reducing noise at lower exposure levels
Technique Selections
What are some factors that technologist must take into consideration when selecting a technique
What regulates that technologists to select appropriate techniques in FS CR amp DR
Screen Film
Self regulating system The receptor speed and film HampD curve defined
the proper exposure Achieving optimal OD guaranteed appropriate
exposure to the patient Over exposed = dark image Correct exposure = correct OD Under exposed = light image
Characteristic curveof radiographic film
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 5: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/5.jpg)
First-generation CT unit dedicated head scanner
(Photograph taken at Roentgen Museum Lennep Germany)
Digital Imaging Techniques
Are used inComputed TomographyMagnetic Resonance ImagingDiagnostic UltrasoundComputerized RadiographyDigital RadiographyDigital Fluoroscopy
CR amp DR imaging
Was limited until sufficient computer technology became available to process the large quantities of data generated
Clinical use began in the 1980rsquos (CR)
1990rsquos (DDR)
Methods to Digitize an Imagebull 1 Film Digitizer - Teleradiography system
(PACS DICOM)
bull 2 Video Camera (vidicon or plumbicon)
bull 3 Computed Radiography
bull 4 Direct Radiography
Computed Radiography Terms
PSL = photostimulable luminescence PSP = photostimulable phosphor SPS = storage phosphor screen IP = imaging plate SP = storage phosphor PMT = photomultiplier tube PD = photodiode SF = screen-film
Computed Radiography
Fundamentals of
Computerized Radiography
CR IR
Cassette-based digital radiography
In SF the intensifying screens contain phosphor that emits light in response to x-ray interaction
In CR the response to x-ray interaction is trapped photon energy (e-) on the PSP plate
Conventional radiography latent image formation
CR latent image formation
What Is Digital ImagingDigital imaging is the acquisition of
images to a computer rather than directly to film
15
IMAGE CREATION
SAME RADIOGRAPHY EQUIPMENT USED
THE DIFFERENCE IS HOW IT IS CAPTURED
STORED VIEWED And POST -PROCESSED
General Overview CR
PSP cassette exposed by conventional x-ray equipment
Latent image generated as a matrix of trapped electrons in the PSP plate
CR BASICS
bull Eliminates the need for film as a recording storage amp viewing medium
bull PSP Plate ndash receiverbull Archive Manager ndash storagebull Monitor - Viewing
Digital
Radiography
DirectCapture
IndirectCapture
Direct-to-DigitalRadiography
(DDR)-Selenium
ComputedRadiography
(CR) - PSL
LaserScanningDigitizers
Direct-to-DigitalRadiographySilicon Scint
DDR CR
CR SYSTEM COMPONENTS
CASSETTES (phosphor plates) ID STATION IMAGE PREVIEW (QC)
STATION DIGITIZER VIEWING STATION
ID STATIONID STATION
CR Readers
AKA
CR Processors
Fuji Agfa Kodak
Computed Radiographic Readers
CR ndash PSP plate
photostimulable phosphor (PSP) plate
Exit photons energizes the PSP plate
The energy is stored in traps on plate (latent image)
PLATE scanned in CR READER
Imaging Plate (IP)
Contained in a cassette
Handled the same as SF cassettes
Processed more like daylight processor with no chemicals
IP has lead backing to reduce scatter
Imaging Plate Construction
A thin sheet of plastic
IPrsquos have several layersA protective layer This is a very thin tough
clear plastic that protects the phosphor layer A phosphor or active layer This is a layer of
photostimulable phosphor that ldquotrapsrdquo electrons during exposure
Active Layer - Crystals The materials that make up the PSP plate
are from the barium fluorohalide family
Barium fluorohalide chlorohalide or bromohalide crystals The most common crystal uses is barium fluorohalide with europium
Acquiring the Image
The remnant beam interacts with electrons in the barium fluorohalide crystals
This interaction stimulates or gives energy to electrons in the crystals allowing them to enter the conductive layer
The Conductuve layer is where they are
trapped in an area of the crystal known as the color or phosphor center
Acquiring the Image cont
This trapped signal will remain for hours even days although deterioration begins almost immediately IR should be processed as soon as possible
The trapped signal is never completely lost
Imaging Plate Construction
A reflective layer This is a layer that sends light in a forward direction when released in the cassette reader This layer may be black to reduce the spread of stimulating light and the escape of emitted light Some detail is lost in this process
Imaging Plate Construction Conductive layer This is a layer of material that
absorbs and reduces static electricity A color layer Newer plates may contain a color
layer located between the active layer and the support that absorbs the stimulating light but reflects emitted light
A support layer This is a semirigid material that gives the imaging sheet some strength
A backing layer This is a soft polymer that protects the back of the cassette
Cross section of a PSP screen
Needle PSP increase the absorption of x-rays and limit the spread of light emission
IP Design
Designed to optimize the intensity of light release (CE)
Enhance the absorption of x-rays (DQE)
Limit the spread of light emission for more detail
Photostimulable Luminescence When the cassette is put into the reader the
imaging plate is extracted and scanned With a helium laser beam or in more recent
systems solid-state laser diodes This beam about 100μm wide with a wavelength
of 633 nm (or 670 to 690 nm for solid state) Scans the plate with red light in a raster pattern
and gives energy to the trapped electrons
X-ray interaction with a PSP screen
1
2
X-ray interactions with the screen phosphors causes an e- to excited
When e- return to groundstate visible light is emitted
CR Phosphor PlatesCR Phosphor Plates
ABSORPTION EMISSION
X-RAY
LIGHT
LASER STIMULATION
ELECTRONTRAP
ELECTRONTRAP
CR Reader ndash PSP plate
Stimulates the matrix of trapped E- by a RED OR ULTRAVIOLET laser light
Trapped E- energy is released in a form of VIOLETBLUE light
Violet light is captured by PMT ndash is amplified and converted into a digital signal
Sequence of CR imaging
PMT
Beam deflector
LaserSource
Light channeling guide
Plate translation Sub-scan direction
Laser beam Scan direction
Output Signal
Reference detec tor
Beam splitter
Cylindrical m irrorf-thetalens
Amplifier
ADC
To imageprocessor
How CR works
Released light is captured by a PMT (photo
multiplier tube) An ultrasensitive photomultiplier tube or CCD (charged couple device)
PSP light is amplified by the PMT or CCD
This light is sent to the analog to digital converter (ADC) To convert light to binary
PMT (photomultiplier tube) The intensity (brightness) of the light ndash
correlates to the density on the image
So lots of light will correlate to what size number amp what color on the image
The digital numeric values are stored in matrix form called pixels for display on a cathode ray tube (CRT) or printed on film
ERASING THE SCREEN ~50 of trapped electrons released during ldquoreadrdquo After image is recorded Plate is erased with high intensity white light and
re-used Erasing should be done after every exposure or
at minimum every 24 hours to avoid ghosting on future images
Basics of Digital Images
bull digital images are a (matrix) of pixel (picture element) values
Pixels Digital images are made of discrete picture
elements arranged in a matrix The size of the image is described in the binary number system
Modern imaging systems are at least 1024 x 1024
4096 x 4096 is being developed for digital radiography
Matrix = each cell corresponds to a specific location on the image
Pixel
Pixels
Digital Images ndash Bit Depth
bull Pixel values can be any bit depth (values from 0 to 1023)
bull Bit depth = or gray shades available for image display
bull Image contrast can be manipulated to stretched or contracted to alter the displayed contrast
bull Typically use ldquowindow widthrdquo and ldquowindow levelrdquo to alter displayed contrast and brightness
Digital - Grayscale
Bit depth Number of gray shades
available for display 8 bit 256 10 bit 1024 12 bit 4096 4 bit 16384
Display Bit Depth1 bit 6 bit 8 bit
2 shades 64 shades 256 shades
Computed Radiography As the plate is scanned ldquoreadrdquo data is collected
at a specific frequency = Sampling frequency
Spatial resolution determined by sampling frequency
With some systems the smaller IRrsquos have higher sampling frequencies amp more pixels per mm = more spatial resolution
Signal Loss (reducing image quality) Signal-to-Noise Ratio
Principle source of noise on the image is scatter radiation
Scattering of emitted light off screen
The efficiency of the photomultiplier tubes (PMTs) and photodiodes (PDs)
Improving Signal-to-Noise Ratio
Optical filter is used to prevent the longer-wavelength laser light affecting the image formation
Increasing exposure to IR Newer CR systems are better at reducing noise at lower exposure levels
Technique Selections
What are some factors that technologist must take into consideration when selecting a technique
What regulates that technologists to select appropriate techniques in FS CR amp DR
Screen Film
Self regulating system The receptor speed and film HampD curve defined
the proper exposure Achieving optimal OD guaranteed appropriate
exposure to the patient Over exposed = dark image Correct exposure = correct OD Under exposed = light image
Characteristic curveof radiographic film
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 6: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/6.jpg)
Digital Imaging Techniques
Are used inComputed TomographyMagnetic Resonance ImagingDiagnostic UltrasoundComputerized RadiographyDigital RadiographyDigital Fluoroscopy
CR amp DR imaging
Was limited until sufficient computer technology became available to process the large quantities of data generated
Clinical use began in the 1980rsquos (CR)
1990rsquos (DDR)
Methods to Digitize an Imagebull 1 Film Digitizer - Teleradiography system
(PACS DICOM)
bull 2 Video Camera (vidicon or plumbicon)
bull 3 Computed Radiography
bull 4 Direct Radiography
Computed Radiography Terms
PSL = photostimulable luminescence PSP = photostimulable phosphor SPS = storage phosphor screen IP = imaging plate SP = storage phosphor PMT = photomultiplier tube PD = photodiode SF = screen-film
Computed Radiography
Fundamentals of
Computerized Radiography
CR IR
Cassette-based digital radiography
In SF the intensifying screens contain phosphor that emits light in response to x-ray interaction
In CR the response to x-ray interaction is trapped photon energy (e-) on the PSP plate
Conventional radiography latent image formation
CR latent image formation
What Is Digital ImagingDigital imaging is the acquisition of
images to a computer rather than directly to film
15
IMAGE CREATION
SAME RADIOGRAPHY EQUIPMENT USED
THE DIFFERENCE IS HOW IT IS CAPTURED
STORED VIEWED And POST -PROCESSED
General Overview CR
PSP cassette exposed by conventional x-ray equipment
Latent image generated as a matrix of trapped electrons in the PSP plate
CR BASICS
bull Eliminates the need for film as a recording storage amp viewing medium
bull PSP Plate ndash receiverbull Archive Manager ndash storagebull Monitor - Viewing
Digital
Radiography
DirectCapture
IndirectCapture
Direct-to-DigitalRadiography
(DDR)-Selenium
ComputedRadiography
(CR) - PSL
LaserScanningDigitizers
Direct-to-DigitalRadiographySilicon Scint
DDR CR
CR SYSTEM COMPONENTS
CASSETTES (phosphor plates) ID STATION IMAGE PREVIEW (QC)
STATION DIGITIZER VIEWING STATION
ID STATIONID STATION
CR Readers
AKA
CR Processors
Fuji Agfa Kodak
Computed Radiographic Readers
CR ndash PSP plate
photostimulable phosphor (PSP) plate
Exit photons energizes the PSP plate
The energy is stored in traps on plate (latent image)
PLATE scanned in CR READER
Imaging Plate (IP)
Contained in a cassette
Handled the same as SF cassettes
Processed more like daylight processor with no chemicals
IP has lead backing to reduce scatter
Imaging Plate Construction
A thin sheet of plastic
IPrsquos have several layersA protective layer This is a very thin tough
clear plastic that protects the phosphor layer A phosphor or active layer This is a layer of
photostimulable phosphor that ldquotrapsrdquo electrons during exposure
Active Layer - Crystals The materials that make up the PSP plate
are from the barium fluorohalide family
Barium fluorohalide chlorohalide or bromohalide crystals The most common crystal uses is barium fluorohalide with europium
Acquiring the Image
The remnant beam interacts with electrons in the barium fluorohalide crystals
This interaction stimulates or gives energy to electrons in the crystals allowing them to enter the conductive layer
The Conductuve layer is where they are
trapped in an area of the crystal known as the color or phosphor center
Acquiring the Image cont
This trapped signal will remain for hours even days although deterioration begins almost immediately IR should be processed as soon as possible
The trapped signal is never completely lost
Imaging Plate Construction
A reflective layer This is a layer that sends light in a forward direction when released in the cassette reader This layer may be black to reduce the spread of stimulating light and the escape of emitted light Some detail is lost in this process
Imaging Plate Construction Conductive layer This is a layer of material that
absorbs and reduces static electricity A color layer Newer plates may contain a color
layer located between the active layer and the support that absorbs the stimulating light but reflects emitted light
A support layer This is a semirigid material that gives the imaging sheet some strength
A backing layer This is a soft polymer that protects the back of the cassette
Cross section of a PSP screen
Needle PSP increase the absorption of x-rays and limit the spread of light emission
IP Design
Designed to optimize the intensity of light release (CE)
Enhance the absorption of x-rays (DQE)
Limit the spread of light emission for more detail
Photostimulable Luminescence When the cassette is put into the reader the
imaging plate is extracted and scanned With a helium laser beam or in more recent
systems solid-state laser diodes This beam about 100μm wide with a wavelength
of 633 nm (or 670 to 690 nm for solid state) Scans the plate with red light in a raster pattern
and gives energy to the trapped electrons
X-ray interaction with a PSP screen
1
2
X-ray interactions with the screen phosphors causes an e- to excited
When e- return to groundstate visible light is emitted
CR Phosphor PlatesCR Phosphor Plates
ABSORPTION EMISSION
X-RAY
LIGHT
LASER STIMULATION
ELECTRONTRAP
ELECTRONTRAP
CR Reader ndash PSP plate
Stimulates the matrix of trapped E- by a RED OR ULTRAVIOLET laser light
Trapped E- energy is released in a form of VIOLETBLUE light
Violet light is captured by PMT ndash is amplified and converted into a digital signal
Sequence of CR imaging
PMT
Beam deflector
LaserSource
Light channeling guide
Plate translation Sub-scan direction
Laser beam Scan direction
Output Signal
Reference detec tor
Beam splitter
Cylindrical m irrorf-thetalens
Amplifier
ADC
To imageprocessor
How CR works
Released light is captured by a PMT (photo
multiplier tube) An ultrasensitive photomultiplier tube or CCD (charged couple device)
PSP light is amplified by the PMT or CCD
This light is sent to the analog to digital converter (ADC) To convert light to binary
PMT (photomultiplier tube) The intensity (brightness) of the light ndash
correlates to the density on the image
So lots of light will correlate to what size number amp what color on the image
The digital numeric values are stored in matrix form called pixels for display on a cathode ray tube (CRT) or printed on film
ERASING THE SCREEN ~50 of trapped electrons released during ldquoreadrdquo After image is recorded Plate is erased with high intensity white light and
re-used Erasing should be done after every exposure or
at minimum every 24 hours to avoid ghosting on future images
Basics of Digital Images
bull digital images are a (matrix) of pixel (picture element) values
Pixels Digital images are made of discrete picture
elements arranged in a matrix The size of the image is described in the binary number system
Modern imaging systems are at least 1024 x 1024
4096 x 4096 is being developed for digital radiography
Matrix = each cell corresponds to a specific location on the image
Pixel
Pixels
Digital Images ndash Bit Depth
bull Pixel values can be any bit depth (values from 0 to 1023)
bull Bit depth = or gray shades available for image display
bull Image contrast can be manipulated to stretched or contracted to alter the displayed contrast
bull Typically use ldquowindow widthrdquo and ldquowindow levelrdquo to alter displayed contrast and brightness
Digital - Grayscale
Bit depth Number of gray shades
available for display 8 bit 256 10 bit 1024 12 bit 4096 4 bit 16384
Display Bit Depth1 bit 6 bit 8 bit
2 shades 64 shades 256 shades
Computed Radiography As the plate is scanned ldquoreadrdquo data is collected
at a specific frequency = Sampling frequency
Spatial resolution determined by sampling frequency
With some systems the smaller IRrsquos have higher sampling frequencies amp more pixels per mm = more spatial resolution
Signal Loss (reducing image quality) Signal-to-Noise Ratio
Principle source of noise on the image is scatter radiation
Scattering of emitted light off screen
The efficiency of the photomultiplier tubes (PMTs) and photodiodes (PDs)
Improving Signal-to-Noise Ratio
Optical filter is used to prevent the longer-wavelength laser light affecting the image formation
Increasing exposure to IR Newer CR systems are better at reducing noise at lower exposure levels
Technique Selections
What are some factors that technologist must take into consideration when selecting a technique
What regulates that technologists to select appropriate techniques in FS CR amp DR
Screen Film
Self regulating system The receptor speed and film HampD curve defined
the proper exposure Achieving optimal OD guaranteed appropriate
exposure to the patient Over exposed = dark image Correct exposure = correct OD Under exposed = light image
Characteristic curveof radiographic film
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 7: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/7.jpg)
CR amp DR imaging
Was limited until sufficient computer technology became available to process the large quantities of data generated
Clinical use began in the 1980rsquos (CR)
1990rsquos (DDR)
Methods to Digitize an Imagebull 1 Film Digitizer - Teleradiography system
(PACS DICOM)
bull 2 Video Camera (vidicon or plumbicon)
bull 3 Computed Radiography
bull 4 Direct Radiography
Computed Radiography Terms
PSL = photostimulable luminescence PSP = photostimulable phosphor SPS = storage phosphor screen IP = imaging plate SP = storage phosphor PMT = photomultiplier tube PD = photodiode SF = screen-film
Computed Radiography
Fundamentals of
Computerized Radiography
CR IR
Cassette-based digital radiography
In SF the intensifying screens contain phosphor that emits light in response to x-ray interaction
In CR the response to x-ray interaction is trapped photon energy (e-) on the PSP plate
Conventional radiography latent image formation
CR latent image formation
What Is Digital ImagingDigital imaging is the acquisition of
images to a computer rather than directly to film
15
IMAGE CREATION
SAME RADIOGRAPHY EQUIPMENT USED
THE DIFFERENCE IS HOW IT IS CAPTURED
STORED VIEWED And POST -PROCESSED
General Overview CR
PSP cassette exposed by conventional x-ray equipment
Latent image generated as a matrix of trapped electrons in the PSP plate
CR BASICS
bull Eliminates the need for film as a recording storage amp viewing medium
bull PSP Plate ndash receiverbull Archive Manager ndash storagebull Monitor - Viewing
Digital
Radiography
DirectCapture
IndirectCapture
Direct-to-DigitalRadiography
(DDR)-Selenium
ComputedRadiography
(CR) - PSL
LaserScanningDigitizers
Direct-to-DigitalRadiographySilicon Scint
DDR CR
CR SYSTEM COMPONENTS
CASSETTES (phosphor plates) ID STATION IMAGE PREVIEW (QC)
STATION DIGITIZER VIEWING STATION
ID STATIONID STATION
CR Readers
AKA
CR Processors
Fuji Agfa Kodak
Computed Radiographic Readers
CR ndash PSP plate
photostimulable phosphor (PSP) plate
Exit photons energizes the PSP plate
The energy is stored in traps on plate (latent image)
PLATE scanned in CR READER
Imaging Plate (IP)
Contained in a cassette
Handled the same as SF cassettes
Processed more like daylight processor with no chemicals
IP has lead backing to reduce scatter
Imaging Plate Construction
A thin sheet of plastic
IPrsquos have several layersA protective layer This is a very thin tough
clear plastic that protects the phosphor layer A phosphor or active layer This is a layer of
photostimulable phosphor that ldquotrapsrdquo electrons during exposure
Active Layer - Crystals The materials that make up the PSP plate
are from the barium fluorohalide family
Barium fluorohalide chlorohalide or bromohalide crystals The most common crystal uses is barium fluorohalide with europium
Acquiring the Image
The remnant beam interacts with electrons in the barium fluorohalide crystals
This interaction stimulates or gives energy to electrons in the crystals allowing them to enter the conductive layer
The Conductuve layer is where they are
trapped in an area of the crystal known as the color or phosphor center
Acquiring the Image cont
This trapped signal will remain for hours even days although deterioration begins almost immediately IR should be processed as soon as possible
The trapped signal is never completely lost
Imaging Plate Construction
A reflective layer This is a layer that sends light in a forward direction when released in the cassette reader This layer may be black to reduce the spread of stimulating light and the escape of emitted light Some detail is lost in this process
Imaging Plate Construction Conductive layer This is a layer of material that
absorbs and reduces static electricity A color layer Newer plates may contain a color
layer located between the active layer and the support that absorbs the stimulating light but reflects emitted light
A support layer This is a semirigid material that gives the imaging sheet some strength
A backing layer This is a soft polymer that protects the back of the cassette
Cross section of a PSP screen
Needle PSP increase the absorption of x-rays and limit the spread of light emission
IP Design
Designed to optimize the intensity of light release (CE)
Enhance the absorption of x-rays (DQE)
Limit the spread of light emission for more detail
Photostimulable Luminescence When the cassette is put into the reader the
imaging plate is extracted and scanned With a helium laser beam or in more recent
systems solid-state laser diodes This beam about 100μm wide with a wavelength
of 633 nm (or 670 to 690 nm for solid state) Scans the plate with red light in a raster pattern
and gives energy to the trapped electrons
X-ray interaction with a PSP screen
1
2
X-ray interactions with the screen phosphors causes an e- to excited
When e- return to groundstate visible light is emitted
CR Phosphor PlatesCR Phosphor Plates
ABSORPTION EMISSION
X-RAY
LIGHT
LASER STIMULATION
ELECTRONTRAP
ELECTRONTRAP
CR Reader ndash PSP plate
Stimulates the matrix of trapped E- by a RED OR ULTRAVIOLET laser light
Trapped E- energy is released in a form of VIOLETBLUE light
Violet light is captured by PMT ndash is amplified and converted into a digital signal
Sequence of CR imaging
PMT
Beam deflector
LaserSource
Light channeling guide
Plate translation Sub-scan direction
Laser beam Scan direction
Output Signal
Reference detec tor
Beam splitter
Cylindrical m irrorf-thetalens
Amplifier
ADC
To imageprocessor
How CR works
Released light is captured by a PMT (photo
multiplier tube) An ultrasensitive photomultiplier tube or CCD (charged couple device)
PSP light is amplified by the PMT or CCD
This light is sent to the analog to digital converter (ADC) To convert light to binary
PMT (photomultiplier tube) The intensity (brightness) of the light ndash
correlates to the density on the image
So lots of light will correlate to what size number amp what color on the image
The digital numeric values are stored in matrix form called pixels for display on a cathode ray tube (CRT) or printed on film
ERASING THE SCREEN ~50 of trapped electrons released during ldquoreadrdquo After image is recorded Plate is erased with high intensity white light and
re-used Erasing should be done after every exposure or
at minimum every 24 hours to avoid ghosting on future images
Basics of Digital Images
bull digital images are a (matrix) of pixel (picture element) values
Pixels Digital images are made of discrete picture
elements arranged in a matrix The size of the image is described in the binary number system
Modern imaging systems are at least 1024 x 1024
4096 x 4096 is being developed for digital radiography
Matrix = each cell corresponds to a specific location on the image
Pixel
Pixels
Digital Images ndash Bit Depth
bull Pixel values can be any bit depth (values from 0 to 1023)
bull Bit depth = or gray shades available for image display
bull Image contrast can be manipulated to stretched or contracted to alter the displayed contrast
bull Typically use ldquowindow widthrdquo and ldquowindow levelrdquo to alter displayed contrast and brightness
Digital - Grayscale
Bit depth Number of gray shades
available for display 8 bit 256 10 bit 1024 12 bit 4096 4 bit 16384
Display Bit Depth1 bit 6 bit 8 bit
2 shades 64 shades 256 shades
Computed Radiography As the plate is scanned ldquoreadrdquo data is collected
at a specific frequency = Sampling frequency
Spatial resolution determined by sampling frequency
With some systems the smaller IRrsquos have higher sampling frequencies amp more pixels per mm = more spatial resolution
Signal Loss (reducing image quality) Signal-to-Noise Ratio
Principle source of noise on the image is scatter radiation
Scattering of emitted light off screen
The efficiency of the photomultiplier tubes (PMTs) and photodiodes (PDs)
Improving Signal-to-Noise Ratio
Optical filter is used to prevent the longer-wavelength laser light affecting the image formation
Increasing exposure to IR Newer CR systems are better at reducing noise at lower exposure levels
Technique Selections
What are some factors that technologist must take into consideration when selecting a technique
What regulates that technologists to select appropriate techniques in FS CR amp DR
Screen Film
Self regulating system The receptor speed and film HampD curve defined
the proper exposure Achieving optimal OD guaranteed appropriate
exposure to the patient Over exposed = dark image Correct exposure = correct OD Under exposed = light image
Characteristic curveof radiographic film
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 8: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/8.jpg)
Methods to Digitize an Imagebull 1 Film Digitizer - Teleradiography system
(PACS DICOM)
bull 2 Video Camera (vidicon or plumbicon)
bull 3 Computed Radiography
bull 4 Direct Radiography
Computed Radiography Terms
PSL = photostimulable luminescence PSP = photostimulable phosphor SPS = storage phosphor screen IP = imaging plate SP = storage phosphor PMT = photomultiplier tube PD = photodiode SF = screen-film
Computed Radiography
Fundamentals of
Computerized Radiography
CR IR
Cassette-based digital radiography
In SF the intensifying screens contain phosphor that emits light in response to x-ray interaction
In CR the response to x-ray interaction is trapped photon energy (e-) on the PSP plate
Conventional radiography latent image formation
CR latent image formation
What Is Digital ImagingDigital imaging is the acquisition of
images to a computer rather than directly to film
15
IMAGE CREATION
SAME RADIOGRAPHY EQUIPMENT USED
THE DIFFERENCE IS HOW IT IS CAPTURED
STORED VIEWED And POST -PROCESSED
General Overview CR
PSP cassette exposed by conventional x-ray equipment
Latent image generated as a matrix of trapped electrons in the PSP plate
CR BASICS
bull Eliminates the need for film as a recording storage amp viewing medium
bull PSP Plate ndash receiverbull Archive Manager ndash storagebull Monitor - Viewing
Digital
Radiography
DirectCapture
IndirectCapture
Direct-to-DigitalRadiography
(DDR)-Selenium
ComputedRadiography
(CR) - PSL
LaserScanningDigitizers
Direct-to-DigitalRadiographySilicon Scint
DDR CR
CR SYSTEM COMPONENTS
CASSETTES (phosphor plates) ID STATION IMAGE PREVIEW (QC)
STATION DIGITIZER VIEWING STATION
ID STATIONID STATION
CR Readers
AKA
CR Processors
Fuji Agfa Kodak
Computed Radiographic Readers
CR ndash PSP plate
photostimulable phosphor (PSP) plate
Exit photons energizes the PSP plate
The energy is stored in traps on plate (latent image)
PLATE scanned in CR READER
Imaging Plate (IP)
Contained in a cassette
Handled the same as SF cassettes
Processed more like daylight processor with no chemicals
IP has lead backing to reduce scatter
Imaging Plate Construction
A thin sheet of plastic
IPrsquos have several layersA protective layer This is a very thin tough
clear plastic that protects the phosphor layer A phosphor or active layer This is a layer of
photostimulable phosphor that ldquotrapsrdquo electrons during exposure
Active Layer - Crystals The materials that make up the PSP plate
are from the barium fluorohalide family
Barium fluorohalide chlorohalide or bromohalide crystals The most common crystal uses is barium fluorohalide with europium
Acquiring the Image
The remnant beam interacts with electrons in the barium fluorohalide crystals
This interaction stimulates or gives energy to electrons in the crystals allowing them to enter the conductive layer
The Conductuve layer is where they are
trapped in an area of the crystal known as the color or phosphor center
Acquiring the Image cont
This trapped signal will remain for hours even days although deterioration begins almost immediately IR should be processed as soon as possible
The trapped signal is never completely lost
Imaging Plate Construction
A reflective layer This is a layer that sends light in a forward direction when released in the cassette reader This layer may be black to reduce the spread of stimulating light and the escape of emitted light Some detail is lost in this process
Imaging Plate Construction Conductive layer This is a layer of material that
absorbs and reduces static electricity A color layer Newer plates may contain a color
layer located between the active layer and the support that absorbs the stimulating light but reflects emitted light
A support layer This is a semirigid material that gives the imaging sheet some strength
A backing layer This is a soft polymer that protects the back of the cassette
Cross section of a PSP screen
Needle PSP increase the absorption of x-rays and limit the spread of light emission
IP Design
Designed to optimize the intensity of light release (CE)
Enhance the absorption of x-rays (DQE)
Limit the spread of light emission for more detail
Photostimulable Luminescence When the cassette is put into the reader the
imaging plate is extracted and scanned With a helium laser beam or in more recent
systems solid-state laser diodes This beam about 100μm wide with a wavelength
of 633 nm (or 670 to 690 nm for solid state) Scans the plate with red light in a raster pattern
and gives energy to the trapped electrons
X-ray interaction with a PSP screen
1
2
X-ray interactions with the screen phosphors causes an e- to excited
When e- return to groundstate visible light is emitted
CR Phosphor PlatesCR Phosphor Plates
ABSORPTION EMISSION
X-RAY
LIGHT
LASER STIMULATION
ELECTRONTRAP
ELECTRONTRAP
CR Reader ndash PSP plate
Stimulates the matrix of trapped E- by a RED OR ULTRAVIOLET laser light
Trapped E- energy is released in a form of VIOLETBLUE light
Violet light is captured by PMT ndash is amplified and converted into a digital signal
Sequence of CR imaging
PMT
Beam deflector
LaserSource
Light channeling guide
Plate translation Sub-scan direction
Laser beam Scan direction
Output Signal
Reference detec tor
Beam splitter
Cylindrical m irrorf-thetalens
Amplifier
ADC
To imageprocessor
How CR works
Released light is captured by a PMT (photo
multiplier tube) An ultrasensitive photomultiplier tube or CCD (charged couple device)
PSP light is amplified by the PMT or CCD
This light is sent to the analog to digital converter (ADC) To convert light to binary
PMT (photomultiplier tube) The intensity (brightness) of the light ndash
correlates to the density on the image
So lots of light will correlate to what size number amp what color on the image
The digital numeric values are stored in matrix form called pixels for display on a cathode ray tube (CRT) or printed on film
ERASING THE SCREEN ~50 of trapped electrons released during ldquoreadrdquo After image is recorded Plate is erased with high intensity white light and
re-used Erasing should be done after every exposure or
at minimum every 24 hours to avoid ghosting on future images
Basics of Digital Images
bull digital images are a (matrix) of pixel (picture element) values
Pixels Digital images are made of discrete picture
elements arranged in a matrix The size of the image is described in the binary number system
Modern imaging systems are at least 1024 x 1024
4096 x 4096 is being developed for digital radiography
Matrix = each cell corresponds to a specific location on the image
Pixel
Pixels
Digital Images ndash Bit Depth
bull Pixel values can be any bit depth (values from 0 to 1023)
bull Bit depth = or gray shades available for image display
bull Image contrast can be manipulated to stretched or contracted to alter the displayed contrast
bull Typically use ldquowindow widthrdquo and ldquowindow levelrdquo to alter displayed contrast and brightness
Digital - Grayscale
Bit depth Number of gray shades
available for display 8 bit 256 10 bit 1024 12 bit 4096 4 bit 16384
Display Bit Depth1 bit 6 bit 8 bit
2 shades 64 shades 256 shades
Computed Radiography As the plate is scanned ldquoreadrdquo data is collected
at a specific frequency = Sampling frequency
Spatial resolution determined by sampling frequency
With some systems the smaller IRrsquos have higher sampling frequencies amp more pixels per mm = more spatial resolution
Signal Loss (reducing image quality) Signal-to-Noise Ratio
Principle source of noise on the image is scatter radiation
Scattering of emitted light off screen
The efficiency of the photomultiplier tubes (PMTs) and photodiodes (PDs)
Improving Signal-to-Noise Ratio
Optical filter is used to prevent the longer-wavelength laser light affecting the image formation
Increasing exposure to IR Newer CR systems are better at reducing noise at lower exposure levels
Technique Selections
What are some factors that technologist must take into consideration when selecting a technique
What regulates that technologists to select appropriate techniques in FS CR amp DR
Screen Film
Self regulating system The receptor speed and film HampD curve defined
the proper exposure Achieving optimal OD guaranteed appropriate
exposure to the patient Over exposed = dark image Correct exposure = correct OD Under exposed = light image
Characteristic curveof radiographic film
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 9: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/9.jpg)
Computed Radiography Terms
PSL = photostimulable luminescence PSP = photostimulable phosphor SPS = storage phosphor screen IP = imaging plate SP = storage phosphor PMT = photomultiplier tube PD = photodiode SF = screen-film
Computed Radiography
Fundamentals of
Computerized Radiography
CR IR
Cassette-based digital radiography
In SF the intensifying screens contain phosphor that emits light in response to x-ray interaction
In CR the response to x-ray interaction is trapped photon energy (e-) on the PSP plate
Conventional radiography latent image formation
CR latent image formation
What Is Digital ImagingDigital imaging is the acquisition of
images to a computer rather than directly to film
15
IMAGE CREATION
SAME RADIOGRAPHY EQUIPMENT USED
THE DIFFERENCE IS HOW IT IS CAPTURED
STORED VIEWED And POST -PROCESSED
General Overview CR
PSP cassette exposed by conventional x-ray equipment
Latent image generated as a matrix of trapped electrons in the PSP plate
CR BASICS
bull Eliminates the need for film as a recording storage amp viewing medium
bull PSP Plate ndash receiverbull Archive Manager ndash storagebull Monitor - Viewing
Digital
Radiography
DirectCapture
IndirectCapture
Direct-to-DigitalRadiography
(DDR)-Selenium
ComputedRadiography
(CR) - PSL
LaserScanningDigitizers
Direct-to-DigitalRadiographySilicon Scint
DDR CR
CR SYSTEM COMPONENTS
CASSETTES (phosphor plates) ID STATION IMAGE PREVIEW (QC)
STATION DIGITIZER VIEWING STATION
ID STATIONID STATION
CR Readers
AKA
CR Processors
Fuji Agfa Kodak
Computed Radiographic Readers
CR ndash PSP plate
photostimulable phosphor (PSP) plate
Exit photons energizes the PSP plate
The energy is stored in traps on plate (latent image)
PLATE scanned in CR READER
Imaging Plate (IP)
Contained in a cassette
Handled the same as SF cassettes
Processed more like daylight processor with no chemicals
IP has lead backing to reduce scatter
Imaging Plate Construction
A thin sheet of plastic
IPrsquos have several layersA protective layer This is a very thin tough
clear plastic that protects the phosphor layer A phosphor or active layer This is a layer of
photostimulable phosphor that ldquotrapsrdquo electrons during exposure
Active Layer - Crystals The materials that make up the PSP plate
are from the barium fluorohalide family
Barium fluorohalide chlorohalide or bromohalide crystals The most common crystal uses is barium fluorohalide with europium
Acquiring the Image
The remnant beam interacts with electrons in the barium fluorohalide crystals
This interaction stimulates or gives energy to electrons in the crystals allowing them to enter the conductive layer
The Conductuve layer is where they are
trapped in an area of the crystal known as the color or phosphor center
Acquiring the Image cont
This trapped signal will remain for hours even days although deterioration begins almost immediately IR should be processed as soon as possible
The trapped signal is never completely lost
Imaging Plate Construction
A reflective layer This is a layer that sends light in a forward direction when released in the cassette reader This layer may be black to reduce the spread of stimulating light and the escape of emitted light Some detail is lost in this process
Imaging Plate Construction Conductive layer This is a layer of material that
absorbs and reduces static electricity A color layer Newer plates may contain a color
layer located between the active layer and the support that absorbs the stimulating light but reflects emitted light
A support layer This is a semirigid material that gives the imaging sheet some strength
A backing layer This is a soft polymer that protects the back of the cassette
Cross section of a PSP screen
Needle PSP increase the absorption of x-rays and limit the spread of light emission
IP Design
Designed to optimize the intensity of light release (CE)
Enhance the absorption of x-rays (DQE)
Limit the spread of light emission for more detail
Photostimulable Luminescence When the cassette is put into the reader the
imaging plate is extracted and scanned With a helium laser beam or in more recent
systems solid-state laser diodes This beam about 100μm wide with a wavelength
of 633 nm (or 670 to 690 nm for solid state) Scans the plate with red light in a raster pattern
and gives energy to the trapped electrons
X-ray interaction with a PSP screen
1
2
X-ray interactions with the screen phosphors causes an e- to excited
When e- return to groundstate visible light is emitted
CR Phosphor PlatesCR Phosphor Plates
ABSORPTION EMISSION
X-RAY
LIGHT
LASER STIMULATION
ELECTRONTRAP
ELECTRONTRAP
CR Reader ndash PSP plate
Stimulates the matrix of trapped E- by a RED OR ULTRAVIOLET laser light
Trapped E- energy is released in a form of VIOLETBLUE light
Violet light is captured by PMT ndash is amplified and converted into a digital signal
Sequence of CR imaging
PMT
Beam deflector
LaserSource
Light channeling guide
Plate translation Sub-scan direction
Laser beam Scan direction
Output Signal
Reference detec tor
Beam splitter
Cylindrical m irrorf-thetalens
Amplifier
ADC
To imageprocessor
How CR works
Released light is captured by a PMT (photo
multiplier tube) An ultrasensitive photomultiplier tube or CCD (charged couple device)
PSP light is amplified by the PMT or CCD
This light is sent to the analog to digital converter (ADC) To convert light to binary
PMT (photomultiplier tube) The intensity (brightness) of the light ndash
correlates to the density on the image
So lots of light will correlate to what size number amp what color on the image
The digital numeric values are stored in matrix form called pixels for display on a cathode ray tube (CRT) or printed on film
ERASING THE SCREEN ~50 of trapped electrons released during ldquoreadrdquo After image is recorded Plate is erased with high intensity white light and
re-used Erasing should be done after every exposure or
at minimum every 24 hours to avoid ghosting on future images
Basics of Digital Images
bull digital images are a (matrix) of pixel (picture element) values
Pixels Digital images are made of discrete picture
elements arranged in a matrix The size of the image is described in the binary number system
Modern imaging systems are at least 1024 x 1024
4096 x 4096 is being developed for digital radiography
Matrix = each cell corresponds to a specific location on the image
Pixel
Pixels
Digital Images ndash Bit Depth
bull Pixel values can be any bit depth (values from 0 to 1023)
bull Bit depth = or gray shades available for image display
bull Image contrast can be manipulated to stretched or contracted to alter the displayed contrast
bull Typically use ldquowindow widthrdquo and ldquowindow levelrdquo to alter displayed contrast and brightness
Digital - Grayscale
Bit depth Number of gray shades
available for display 8 bit 256 10 bit 1024 12 bit 4096 4 bit 16384
Display Bit Depth1 bit 6 bit 8 bit
2 shades 64 shades 256 shades
Computed Radiography As the plate is scanned ldquoreadrdquo data is collected
at a specific frequency = Sampling frequency
Spatial resolution determined by sampling frequency
With some systems the smaller IRrsquos have higher sampling frequencies amp more pixels per mm = more spatial resolution
Signal Loss (reducing image quality) Signal-to-Noise Ratio
Principle source of noise on the image is scatter radiation
Scattering of emitted light off screen
The efficiency of the photomultiplier tubes (PMTs) and photodiodes (PDs)
Improving Signal-to-Noise Ratio
Optical filter is used to prevent the longer-wavelength laser light affecting the image formation
Increasing exposure to IR Newer CR systems are better at reducing noise at lower exposure levels
Technique Selections
What are some factors that technologist must take into consideration when selecting a technique
What regulates that technologists to select appropriate techniques in FS CR amp DR
Screen Film
Self regulating system The receptor speed and film HampD curve defined
the proper exposure Achieving optimal OD guaranteed appropriate
exposure to the patient Over exposed = dark image Correct exposure = correct OD Under exposed = light image
Characteristic curveof radiographic film
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 10: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/10.jpg)
Computed Radiography
Fundamentals of
Computerized Radiography
CR IR
Cassette-based digital radiography
In SF the intensifying screens contain phosphor that emits light in response to x-ray interaction
In CR the response to x-ray interaction is trapped photon energy (e-) on the PSP plate
Conventional radiography latent image formation
CR latent image formation
What Is Digital ImagingDigital imaging is the acquisition of
images to a computer rather than directly to film
15
IMAGE CREATION
SAME RADIOGRAPHY EQUIPMENT USED
THE DIFFERENCE IS HOW IT IS CAPTURED
STORED VIEWED And POST -PROCESSED
General Overview CR
PSP cassette exposed by conventional x-ray equipment
Latent image generated as a matrix of trapped electrons in the PSP plate
CR BASICS
bull Eliminates the need for film as a recording storage amp viewing medium
bull PSP Plate ndash receiverbull Archive Manager ndash storagebull Monitor - Viewing
Digital
Radiography
DirectCapture
IndirectCapture
Direct-to-DigitalRadiography
(DDR)-Selenium
ComputedRadiography
(CR) - PSL
LaserScanningDigitizers
Direct-to-DigitalRadiographySilicon Scint
DDR CR
CR SYSTEM COMPONENTS
CASSETTES (phosphor plates) ID STATION IMAGE PREVIEW (QC)
STATION DIGITIZER VIEWING STATION
ID STATIONID STATION
CR Readers
AKA
CR Processors
Fuji Agfa Kodak
Computed Radiographic Readers
CR ndash PSP plate
photostimulable phosphor (PSP) plate
Exit photons energizes the PSP plate
The energy is stored in traps on plate (latent image)
PLATE scanned in CR READER
Imaging Plate (IP)
Contained in a cassette
Handled the same as SF cassettes
Processed more like daylight processor with no chemicals
IP has lead backing to reduce scatter
Imaging Plate Construction
A thin sheet of plastic
IPrsquos have several layersA protective layer This is a very thin tough
clear plastic that protects the phosphor layer A phosphor or active layer This is a layer of
photostimulable phosphor that ldquotrapsrdquo electrons during exposure
Active Layer - Crystals The materials that make up the PSP plate
are from the barium fluorohalide family
Barium fluorohalide chlorohalide or bromohalide crystals The most common crystal uses is barium fluorohalide with europium
Acquiring the Image
The remnant beam interacts with electrons in the barium fluorohalide crystals
This interaction stimulates or gives energy to electrons in the crystals allowing them to enter the conductive layer
The Conductuve layer is where they are
trapped in an area of the crystal known as the color or phosphor center
Acquiring the Image cont
This trapped signal will remain for hours even days although deterioration begins almost immediately IR should be processed as soon as possible
The trapped signal is never completely lost
Imaging Plate Construction
A reflective layer This is a layer that sends light in a forward direction when released in the cassette reader This layer may be black to reduce the spread of stimulating light and the escape of emitted light Some detail is lost in this process
Imaging Plate Construction Conductive layer This is a layer of material that
absorbs and reduces static electricity A color layer Newer plates may contain a color
layer located between the active layer and the support that absorbs the stimulating light but reflects emitted light
A support layer This is a semirigid material that gives the imaging sheet some strength
A backing layer This is a soft polymer that protects the back of the cassette
Cross section of a PSP screen
Needle PSP increase the absorption of x-rays and limit the spread of light emission
IP Design
Designed to optimize the intensity of light release (CE)
Enhance the absorption of x-rays (DQE)
Limit the spread of light emission for more detail
Photostimulable Luminescence When the cassette is put into the reader the
imaging plate is extracted and scanned With a helium laser beam or in more recent
systems solid-state laser diodes This beam about 100μm wide with a wavelength
of 633 nm (or 670 to 690 nm for solid state) Scans the plate with red light in a raster pattern
and gives energy to the trapped electrons
X-ray interaction with a PSP screen
1
2
X-ray interactions with the screen phosphors causes an e- to excited
When e- return to groundstate visible light is emitted
CR Phosphor PlatesCR Phosphor Plates
ABSORPTION EMISSION
X-RAY
LIGHT
LASER STIMULATION
ELECTRONTRAP
ELECTRONTRAP
CR Reader ndash PSP plate
Stimulates the matrix of trapped E- by a RED OR ULTRAVIOLET laser light
Trapped E- energy is released in a form of VIOLETBLUE light
Violet light is captured by PMT ndash is amplified and converted into a digital signal
Sequence of CR imaging
PMT
Beam deflector
LaserSource
Light channeling guide
Plate translation Sub-scan direction
Laser beam Scan direction
Output Signal
Reference detec tor
Beam splitter
Cylindrical m irrorf-thetalens
Amplifier
ADC
To imageprocessor
How CR works
Released light is captured by a PMT (photo
multiplier tube) An ultrasensitive photomultiplier tube or CCD (charged couple device)
PSP light is amplified by the PMT or CCD
This light is sent to the analog to digital converter (ADC) To convert light to binary
PMT (photomultiplier tube) The intensity (brightness) of the light ndash
correlates to the density on the image
So lots of light will correlate to what size number amp what color on the image
The digital numeric values are stored in matrix form called pixels for display on a cathode ray tube (CRT) or printed on film
ERASING THE SCREEN ~50 of trapped electrons released during ldquoreadrdquo After image is recorded Plate is erased with high intensity white light and
re-used Erasing should be done after every exposure or
at minimum every 24 hours to avoid ghosting on future images
Basics of Digital Images
bull digital images are a (matrix) of pixel (picture element) values
Pixels Digital images are made of discrete picture
elements arranged in a matrix The size of the image is described in the binary number system
Modern imaging systems are at least 1024 x 1024
4096 x 4096 is being developed for digital radiography
Matrix = each cell corresponds to a specific location on the image
Pixel
Pixels
Digital Images ndash Bit Depth
bull Pixel values can be any bit depth (values from 0 to 1023)
bull Bit depth = or gray shades available for image display
bull Image contrast can be manipulated to stretched or contracted to alter the displayed contrast
bull Typically use ldquowindow widthrdquo and ldquowindow levelrdquo to alter displayed contrast and brightness
Digital - Grayscale
Bit depth Number of gray shades
available for display 8 bit 256 10 bit 1024 12 bit 4096 4 bit 16384
Display Bit Depth1 bit 6 bit 8 bit
2 shades 64 shades 256 shades
Computed Radiography As the plate is scanned ldquoreadrdquo data is collected
at a specific frequency = Sampling frequency
Spatial resolution determined by sampling frequency
With some systems the smaller IRrsquos have higher sampling frequencies amp more pixels per mm = more spatial resolution
Signal Loss (reducing image quality) Signal-to-Noise Ratio
Principle source of noise on the image is scatter radiation
Scattering of emitted light off screen
The efficiency of the photomultiplier tubes (PMTs) and photodiodes (PDs)
Improving Signal-to-Noise Ratio
Optical filter is used to prevent the longer-wavelength laser light affecting the image formation
Increasing exposure to IR Newer CR systems are better at reducing noise at lower exposure levels
Technique Selections
What are some factors that technologist must take into consideration when selecting a technique
What regulates that technologists to select appropriate techniques in FS CR amp DR
Screen Film
Self regulating system The receptor speed and film HampD curve defined
the proper exposure Achieving optimal OD guaranteed appropriate
exposure to the patient Over exposed = dark image Correct exposure = correct OD Under exposed = light image
Characteristic curveof radiographic film
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 11: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/11.jpg)
CR IR
Cassette-based digital radiography
In SF the intensifying screens contain phosphor that emits light in response to x-ray interaction
In CR the response to x-ray interaction is trapped photon energy (e-) on the PSP plate
Conventional radiography latent image formation
CR latent image formation
What Is Digital ImagingDigital imaging is the acquisition of
images to a computer rather than directly to film
15
IMAGE CREATION
SAME RADIOGRAPHY EQUIPMENT USED
THE DIFFERENCE IS HOW IT IS CAPTURED
STORED VIEWED And POST -PROCESSED
General Overview CR
PSP cassette exposed by conventional x-ray equipment
Latent image generated as a matrix of trapped electrons in the PSP plate
CR BASICS
bull Eliminates the need for film as a recording storage amp viewing medium
bull PSP Plate ndash receiverbull Archive Manager ndash storagebull Monitor - Viewing
Digital
Radiography
DirectCapture
IndirectCapture
Direct-to-DigitalRadiography
(DDR)-Selenium
ComputedRadiography
(CR) - PSL
LaserScanningDigitizers
Direct-to-DigitalRadiographySilicon Scint
DDR CR
CR SYSTEM COMPONENTS
CASSETTES (phosphor plates) ID STATION IMAGE PREVIEW (QC)
STATION DIGITIZER VIEWING STATION
ID STATIONID STATION
CR Readers
AKA
CR Processors
Fuji Agfa Kodak
Computed Radiographic Readers
CR ndash PSP plate
photostimulable phosphor (PSP) plate
Exit photons energizes the PSP plate
The energy is stored in traps on plate (latent image)
PLATE scanned in CR READER
Imaging Plate (IP)
Contained in a cassette
Handled the same as SF cassettes
Processed more like daylight processor with no chemicals
IP has lead backing to reduce scatter
Imaging Plate Construction
A thin sheet of plastic
IPrsquos have several layersA protective layer This is a very thin tough
clear plastic that protects the phosphor layer A phosphor or active layer This is a layer of
photostimulable phosphor that ldquotrapsrdquo electrons during exposure
Active Layer - Crystals The materials that make up the PSP plate
are from the barium fluorohalide family
Barium fluorohalide chlorohalide or bromohalide crystals The most common crystal uses is barium fluorohalide with europium
Acquiring the Image
The remnant beam interacts with electrons in the barium fluorohalide crystals
This interaction stimulates or gives energy to electrons in the crystals allowing them to enter the conductive layer
The Conductuve layer is where they are
trapped in an area of the crystal known as the color or phosphor center
Acquiring the Image cont
This trapped signal will remain for hours even days although deterioration begins almost immediately IR should be processed as soon as possible
The trapped signal is never completely lost
Imaging Plate Construction
A reflective layer This is a layer that sends light in a forward direction when released in the cassette reader This layer may be black to reduce the spread of stimulating light and the escape of emitted light Some detail is lost in this process
Imaging Plate Construction Conductive layer This is a layer of material that
absorbs and reduces static electricity A color layer Newer plates may contain a color
layer located between the active layer and the support that absorbs the stimulating light but reflects emitted light
A support layer This is a semirigid material that gives the imaging sheet some strength
A backing layer This is a soft polymer that protects the back of the cassette
Cross section of a PSP screen
Needle PSP increase the absorption of x-rays and limit the spread of light emission
IP Design
Designed to optimize the intensity of light release (CE)
Enhance the absorption of x-rays (DQE)
Limit the spread of light emission for more detail
Photostimulable Luminescence When the cassette is put into the reader the
imaging plate is extracted and scanned With a helium laser beam or in more recent
systems solid-state laser diodes This beam about 100μm wide with a wavelength
of 633 nm (or 670 to 690 nm for solid state) Scans the plate with red light in a raster pattern
and gives energy to the trapped electrons
X-ray interaction with a PSP screen
1
2
X-ray interactions with the screen phosphors causes an e- to excited
When e- return to groundstate visible light is emitted
CR Phosphor PlatesCR Phosphor Plates
ABSORPTION EMISSION
X-RAY
LIGHT
LASER STIMULATION
ELECTRONTRAP
ELECTRONTRAP
CR Reader ndash PSP plate
Stimulates the matrix of trapped E- by a RED OR ULTRAVIOLET laser light
Trapped E- energy is released in a form of VIOLETBLUE light
Violet light is captured by PMT ndash is amplified and converted into a digital signal
Sequence of CR imaging
PMT
Beam deflector
LaserSource
Light channeling guide
Plate translation Sub-scan direction
Laser beam Scan direction
Output Signal
Reference detec tor
Beam splitter
Cylindrical m irrorf-thetalens
Amplifier
ADC
To imageprocessor
How CR works
Released light is captured by a PMT (photo
multiplier tube) An ultrasensitive photomultiplier tube or CCD (charged couple device)
PSP light is amplified by the PMT or CCD
This light is sent to the analog to digital converter (ADC) To convert light to binary
PMT (photomultiplier tube) The intensity (brightness) of the light ndash
correlates to the density on the image
So lots of light will correlate to what size number amp what color on the image
The digital numeric values are stored in matrix form called pixels for display on a cathode ray tube (CRT) or printed on film
ERASING THE SCREEN ~50 of trapped electrons released during ldquoreadrdquo After image is recorded Plate is erased with high intensity white light and
re-used Erasing should be done after every exposure or
at minimum every 24 hours to avoid ghosting on future images
Basics of Digital Images
bull digital images are a (matrix) of pixel (picture element) values
Pixels Digital images are made of discrete picture
elements arranged in a matrix The size of the image is described in the binary number system
Modern imaging systems are at least 1024 x 1024
4096 x 4096 is being developed for digital radiography
Matrix = each cell corresponds to a specific location on the image
Pixel
Pixels
Digital Images ndash Bit Depth
bull Pixel values can be any bit depth (values from 0 to 1023)
bull Bit depth = or gray shades available for image display
bull Image contrast can be manipulated to stretched or contracted to alter the displayed contrast
bull Typically use ldquowindow widthrdquo and ldquowindow levelrdquo to alter displayed contrast and brightness
Digital - Grayscale
Bit depth Number of gray shades
available for display 8 bit 256 10 bit 1024 12 bit 4096 4 bit 16384
Display Bit Depth1 bit 6 bit 8 bit
2 shades 64 shades 256 shades
Computed Radiography As the plate is scanned ldquoreadrdquo data is collected
at a specific frequency = Sampling frequency
Spatial resolution determined by sampling frequency
With some systems the smaller IRrsquos have higher sampling frequencies amp more pixels per mm = more spatial resolution
Signal Loss (reducing image quality) Signal-to-Noise Ratio
Principle source of noise on the image is scatter radiation
Scattering of emitted light off screen
The efficiency of the photomultiplier tubes (PMTs) and photodiodes (PDs)
Improving Signal-to-Noise Ratio
Optical filter is used to prevent the longer-wavelength laser light affecting the image formation
Increasing exposure to IR Newer CR systems are better at reducing noise at lower exposure levels
Technique Selections
What are some factors that technologist must take into consideration when selecting a technique
What regulates that technologists to select appropriate techniques in FS CR amp DR
Screen Film
Self regulating system The receptor speed and film HampD curve defined
the proper exposure Achieving optimal OD guaranteed appropriate
exposure to the patient Over exposed = dark image Correct exposure = correct OD Under exposed = light image
Characteristic curveof radiographic film
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 12: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/12.jpg)
Conventional radiography latent image formation
CR latent image formation
What Is Digital ImagingDigital imaging is the acquisition of
images to a computer rather than directly to film
15
IMAGE CREATION
SAME RADIOGRAPHY EQUIPMENT USED
THE DIFFERENCE IS HOW IT IS CAPTURED
STORED VIEWED And POST -PROCESSED
General Overview CR
PSP cassette exposed by conventional x-ray equipment
Latent image generated as a matrix of trapped electrons in the PSP plate
CR BASICS
bull Eliminates the need for film as a recording storage amp viewing medium
bull PSP Plate ndash receiverbull Archive Manager ndash storagebull Monitor - Viewing
Digital
Radiography
DirectCapture
IndirectCapture
Direct-to-DigitalRadiography
(DDR)-Selenium
ComputedRadiography
(CR) - PSL
LaserScanningDigitizers
Direct-to-DigitalRadiographySilicon Scint
DDR CR
CR SYSTEM COMPONENTS
CASSETTES (phosphor plates) ID STATION IMAGE PREVIEW (QC)
STATION DIGITIZER VIEWING STATION
ID STATIONID STATION
CR Readers
AKA
CR Processors
Fuji Agfa Kodak
Computed Radiographic Readers
CR ndash PSP plate
photostimulable phosphor (PSP) plate
Exit photons energizes the PSP plate
The energy is stored in traps on plate (latent image)
PLATE scanned in CR READER
Imaging Plate (IP)
Contained in a cassette
Handled the same as SF cassettes
Processed more like daylight processor with no chemicals
IP has lead backing to reduce scatter
Imaging Plate Construction
A thin sheet of plastic
IPrsquos have several layersA protective layer This is a very thin tough
clear plastic that protects the phosphor layer A phosphor or active layer This is a layer of
photostimulable phosphor that ldquotrapsrdquo electrons during exposure
Active Layer - Crystals The materials that make up the PSP plate
are from the barium fluorohalide family
Barium fluorohalide chlorohalide or bromohalide crystals The most common crystal uses is barium fluorohalide with europium
Acquiring the Image
The remnant beam interacts with electrons in the barium fluorohalide crystals
This interaction stimulates or gives energy to electrons in the crystals allowing them to enter the conductive layer
The Conductuve layer is where they are
trapped in an area of the crystal known as the color or phosphor center
Acquiring the Image cont
This trapped signal will remain for hours even days although deterioration begins almost immediately IR should be processed as soon as possible
The trapped signal is never completely lost
Imaging Plate Construction
A reflective layer This is a layer that sends light in a forward direction when released in the cassette reader This layer may be black to reduce the spread of stimulating light and the escape of emitted light Some detail is lost in this process
Imaging Plate Construction Conductive layer This is a layer of material that
absorbs and reduces static electricity A color layer Newer plates may contain a color
layer located between the active layer and the support that absorbs the stimulating light but reflects emitted light
A support layer This is a semirigid material that gives the imaging sheet some strength
A backing layer This is a soft polymer that protects the back of the cassette
Cross section of a PSP screen
Needle PSP increase the absorption of x-rays and limit the spread of light emission
IP Design
Designed to optimize the intensity of light release (CE)
Enhance the absorption of x-rays (DQE)
Limit the spread of light emission for more detail
Photostimulable Luminescence When the cassette is put into the reader the
imaging plate is extracted and scanned With a helium laser beam or in more recent
systems solid-state laser diodes This beam about 100μm wide with a wavelength
of 633 nm (or 670 to 690 nm for solid state) Scans the plate with red light in a raster pattern
and gives energy to the trapped electrons
X-ray interaction with a PSP screen
1
2
X-ray interactions with the screen phosphors causes an e- to excited
When e- return to groundstate visible light is emitted
CR Phosphor PlatesCR Phosphor Plates
ABSORPTION EMISSION
X-RAY
LIGHT
LASER STIMULATION
ELECTRONTRAP
ELECTRONTRAP
CR Reader ndash PSP plate
Stimulates the matrix of trapped E- by a RED OR ULTRAVIOLET laser light
Trapped E- energy is released in a form of VIOLETBLUE light
Violet light is captured by PMT ndash is amplified and converted into a digital signal
Sequence of CR imaging
PMT
Beam deflector
LaserSource
Light channeling guide
Plate translation Sub-scan direction
Laser beam Scan direction
Output Signal
Reference detec tor
Beam splitter
Cylindrical m irrorf-thetalens
Amplifier
ADC
To imageprocessor
How CR works
Released light is captured by a PMT (photo
multiplier tube) An ultrasensitive photomultiplier tube or CCD (charged couple device)
PSP light is amplified by the PMT or CCD
This light is sent to the analog to digital converter (ADC) To convert light to binary
PMT (photomultiplier tube) The intensity (brightness) of the light ndash
correlates to the density on the image
So lots of light will correlate to what size number amp what color on the image
The digital numeric values are stored in matrix form called pixels for display on a cathode ray tube (CRT) or printed on film
ERASING THE SCREEN ~50 of trapped electrons released during ldquoreadrdquo After image is recorded Plate is erased with high intensity white light and
re-used Erasing should be done after every exposure or
at minimum every 24 hours to avoid ghosting on future images
Basics of Digital Images
bull digital images are a (matrix) of pixel (picture element) values
Pixels Digital images are made of discrete picture
elements arranged in a matrix The size of the image is described in the binary number system
Modern imaging systems are at least 1024 x 1024
4096 x 4096 is being developed for digital radiography
Matrix = each cell corresponds to a specific location on the image
Pixel
Pixels
Digital Images ndash Bit Depth
bull Pixel values can be any bit depth (values from 0 to 1023)
bull Bit depth = or gray shades available for image display
bull Image contrast can be manipulated to stretched or contracted to alter the displayed contrast
bull Typically use ldquowindow widthrdquo and ldquowindow levelrdquo to alter displayed contrast and brightness
Digital - Grayscale
Bit depth Number of gray shades
available for display 8 bit 256 10 bit 1024 12 bit 4096 4 bit 16384
Display Bit Depth1 bit 6 bit 8 bit
2 shades 64 shades 256 shades
Computed Radiography As the plate is scanned ldquoreadrdquo data is collected
at a specific frequency = Sampling frequency
Spatial resolution determined by sampling frequency
With some systems the smaller IRrsquos have higher sampling frequencies amp more pixels per mm = more spatial resolution
Signal Loss (reducing image quality) Signal-to-Noise Ratio
Principle source of noise on the image is scatter radiation
Scattering of emitted light off screen
The efficiency of the photomultiplier tubes (PMTs) and photodiodes (PDs)
Improving Signal-to-Noise Ratio
Optical filter is used to prevent the longer-wavelength laser light affecting the image formation
Increasing exposure to IR Newer CR systems are better at reducing noise at lower exposure levels
Technique Selections
What are some factors that technologist must take into consideration when selecting a technique
What regulates that technologists to select appropriate techniques in FS CR amp DR
Screen Film
Self regulating system The receptor speed and film HampD curve defined
the proper exposure Achieving optimal OD guaranteed appropriate
exposure to the patient Over exposed = dark image Correct exposure = correct OD Under exposed = light image
Characteristic curveof radiographic film
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 13: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/13.jpg)
CR latent image formation
What Is Digital ImagingDigital imaging is the acquisition of
images to a computer rather than directly to film
15
IMAGE CREATION
SAME RADIOGRAPHY EQUIPMENT USED
THE DIFFERENCE IS HOW IT IS CAPTURED
STORED VIEWED And POST -PROCESSED
General Overview CR
PSP cassette exposed by conventional x-ray equipment
Latent image generated as a matrix of trapped electrons in the PSP plate
CR BASICS
bull Eliminates the need for film as a recording storage amp viewing medium
bull PSP Plate ndash receiverbull Archive Manager ndash storagebull Monitor - Viewing
Digital
Radiography
DirectCapture
IndirectCapture
Direct-to-DigitalRadiography
(DDR)-Selenium
ComputedRadiography
(CR) - PSL
LaserScanningDigitizers
Direct-to-DigitalRadiographySilicon Scint
DDR CR
CR SYSTEM COMPONENTS
CASSETTES (phosphor plates) ID STATION IMAGE PREVIEW (QC)
STATION DIGITIZER VIEWING STATION
ID STATIONID STATION
CR Readers
AKA
CR Processors
Fuji Agfa Kodak
Computed Radiographic Readers
CR ndash PSP plate
photostimulable phosphor (PSP) plate
Exit photons energizes the PSP plate
The energy is stored in traps on plate (latent image)
PLATE scanned in CR READER
Imaging Plate (IP)
Contained in a cassette
Handled the same as SF cassettes
Processed more like daylight processor with no chemicals
IP has lead backing to reduce scatter
Imaging Plate Construction
A thin sheet of plastic
IPrsquos have several layersA protective layer This is a very thin tough
clear plastic that protects the phosphor layer A phosphor or active layer This is a layer of
photostimulable phosphor that ldquotrapsrdquo electrons during exposure
Active Layer - Crystals The materials that make up the PSP plate
are from the barium fluorohalide family
Barium fluorohalide chlorohalide or bromohalide crystals The most common crystal uses is barium fluorohalide with europium
Acquiring the Image
The remnant beam interacts with electrons in the barium fluorohalide crystals
This interaction stimulates or gives energy to electrons in the crystals allowing them to enter the conductive layer
The Conductuve layer is where they are
trapped in an area of the crystal known as the color or phosphor center
Acquiring the Image cont
This trapped signal will remain for hours even days although deterioration begins almost immediately IR should be processed as soon as possible
The trapped signal is never completely lost
Imaging Plate Construction
A reflective layer This is a layer that sends light in a forward direction when released in the cassette reader This layer may be black to reduce the spread of stimulating light and the escape of emitted light Some detail is lost in this process
Imaging Plate Construction Conductive layer This is a layer of material that
absorbs and reduces static electricity A color layer Newer plates may contain a color
layer located between the active layer and the support that absorbs the stimulating light but reflects emitted light
A support layer This is a semirigid material that gives the imaging sheet some strength
A backing layer This is a soft polymer that protects the back of the cassette
Cross section of a PSP screen
Needle PSP increase the absorption of x-rays and limit the spread of light emission
IP Design
Designed to optimize the intensity of light release (CE)
Enhance the absorption of x-rays (DQE)
Limit the spread of light emission for more detail
Photostimulable Luminescence When the cassette is put into the reader the
imaging plate is extracted and scanned With a helium laser beam or in more recent
systems solid-state laser diodes This beam about 100μm wide with a wavelength
of 633 nm (or 670 to 690 nm for solid state) Scans the plate with red light in a raster pattern
and gives energy to the trapped electrons
X-ray interaction with a PSP screen
1
2
X-ray interactions with the screen phosphors causes an e- to excited
When e- return to groundstate visible light is emitted
CR Phosphor PlatesCR Phosphor Plates
ABSORPTION EMISSION
X-RAY
LIGHT
LASER STIMULATION
ELECTRONTRAP
ELECTRONTRAP
CR Reader ndash PSP plate
Stimulates the matrix of trapped E- by a RED OR ULTRAVIOLET laser light
Trapped E- energy is released in a form of VIOLETBLUE light
Violet light is captured by PMT ndash is amplified and converted into a digital signal
Sequence of CR imaging
PMT
Beam deflector
LaserSource
Light channeling guide
Plate translation Sub-scan direction
Laser beam Scan direction
Output Signal
Reference detec tor
Beam splitter
Cylindrical m irrorf-thetalens
Amplifier
ADC
To imageprocessor
How CR works
Released light is captured by a PMT (photo
multiplier tube) An ultrasensitive photomultiplier tube or CCD (charged couple device)
PSP light is amplified by the PMT or CCD
This light is sent to the analog to digital converter (ADC) To convert light to binary
PMT (photomultiplier tube) The intensity (brightness) of the light ndash
correlates to the density on the image
So lots of light will correlate to what size number amp what color on the image
The digital numeric values are stored in matrix form called pixels for display on a cathode ray tube (CRT) or printed on film
ERASING THE SCREEN ~50 of trapped electrons released during ldquoreadrdquo After image is recorded Plate is erased with high intensity white light and
re-used Erasing should be done after every exposure or
at minimum every 24 hours to avoid ghosting on future images
Basics of Digital Images
bull digital images are a (matrix) of pixel (picture element) values
Pixels Digital images are made of discrete picture
elements arranged in a matrix The size of the image is described in the binary number system
Modern imaging systems are at least 1024 x 1024
4096 x 4096 is being developed for digital radiography
Matrix = each cell corresponds to a specific location on the image
Pixel
Pixels
Digital Images ndash Bit Depth
bull Pixel values can be any bit depth (values from 0 to 1023)
bull Bit depth = or gray shades available for image display
bull Image contrast can be manipulated to stretched or contracted to alter the displayed contrast
bull Typically use ldquowindow widthrdquo and ldquowindow levelrdquo to alter displayed contrast and brightness
Digital - Grayscale
Bit depth Number of gray shades
available for display 8 bit 256 10 bit 1024 12 bit 4096 4 bit 16384
Display Bit Depth1 bit 6 bit 8 bit
2 shades 64 shades 256 shades
Computed Radiography As the plate is scanned ldquoreadrdquo data is collected
at a specific frequency = Sampling frequency
Spatial resolution determined by sampling frequency
With some systems the smaller IRrsquos have higher sampling frequencies amp more pixels per mm = more spatial resolution
Signal Loss (reducing image quality) Signal-to-Noise Ratio
Principle source of noise on the image is scatter radiation
Scattering of emitted light off screen
The efficiency of the photomultiplier tubes (PMTs) and photodiodes (PDs)
Improving Signal-to-Noise Ratio
Optical filter is used to prevent the longer-wavelength laser light affecting the image formation
Increasing exposure to IR Newer CR systems are better at reducing noise at lower exposure levels
Technique Selections
What are some factors that technologist must take into consideration when selecting a technique
What regulates that technologists to select appropriate techniques in FS CR amp DR
Screen Film
Self regulating system The receptor speed and film HampD curve defined
the proper exposure Achieving optimal OD guaranteed appropriate
exposure to the patient Over exposed = dark image Correct exposure = correct OD Under exposed = light image
Characteristic curveof radiographic film
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 14: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/14.jpg)
What Is Digital ImagingDigital imaging is the acquisition of
images to a computer rather than directly to film
15
IMAGE CREATION
SAME RADIOGRAPHY EQUIPMENT USED
THE DIFFERENCE IS HOW IT IS CAPTURED
STORED VIEWED And POST -PROCESSED
General Overview CR
PSP cassette exposed by conventional x-ray equipment
Latent image generated as a matrix of trapped electrons in the PSP plate
CR BASICS
bull Eliminates the need for film as a recording storage amp viewing medium
bull PSP Plate ndash receiverbull Archive Manager ndash storagebull Monitor - Viewing
Digital
Radiography
DirectCapture
IndirectCapture
Direct-to-DigitalRadiography
(DDR)-Selenium
ComputedRadiography
(CR) - PSL
LaserScanningDigitizers
Direct-to-DigitalRadiographySilicon Scint
DDR CR
CR SYSTEM COMPONENTS
CASSETTES (phosphor plates) ID STATION IMAGE PREVIEW (QC)
STATION DIGITIZER VIEWING STATION
ID STATIONID STATION
CR Readers
AKA
CR Processors
Fuji Agfa Kodak
Computed Radiographic Readers
CR ndash PSP plate
photostimulable phosphor (PSP) plate
Exit photons energizes the PSP plate
The energy is stored in traps on plate (latent image)
PLATE scanned in CR READER
Imaging Plate (IP)
Contained in a cassette
Handled the same as SF cassettes
Processed more like daylight processor with no chemicals
IP has lead backing to reduce scatter
Imaging Plate Construction
A thin sheet of plastic
IPrsquos have several layersA protective layer This is a very thin tough
clear plastic that protects the phosphor layer A phosphor or active layer This is a layer of
photostimulable phosphor that ldquotrapsrdquo electrons during exposure
Active Layer - Crystals The materials that make up the PSP plate
are from the barium fluorohalide family
Barium fluorohalide chlorohalide or bromohalide crystals The most common crystal uses is barium fluorohalide with europium
Acquiring the Image
The remnant beam interacts with electrons in the barium fluorohalide crystals
This interaction stimulates or gives energy to electrons in the crystals allowing them to enter the conductive layer
The Conductuve layer is where they are
trapped in an area of the crystal known as the color or phosphor center
Acquiring the Image cont
This trapped signal will remain for hours even days although deterioration begins almost immediately IR should be processed as soon as possible
The trapped signal is never completely lost
Imaging Plate Construction
A reflective layer This is a layer that sends light in a forward direction when released in the cassette reader This layer may be black to reduce the spread of stimulating light and the escape of emitted light Some detail is lost in this process
Imaging Plate Construction Conductive layer This is a layer of material that
absorbs and reduces static electricity A color layer Newer plates may contain a color
layer located between the active layer and the support that absorbs the stimulating light but reflects emitted light
A support layer This is a semirigid material that gives the imaging sheet some strength
A backing layer This is a soft polymer that protects the back of the cassette
Cross section of a PSP screen
Needle PSP increase the absorption of x-rays and limit the spread of light emission
IP Design
Designed to optimize the intensity of light release (CE)
Enhance the absorption of x-rays (DQE)
Limit the spread of light emission for more detail
Photostimulable Luminescence When the cassette is put into the reader the
imaging plate is extracted and scanned With a helium laser beam or in more recent
systems solid-state laser diodes This beam about 100μm wide with a wavelength
of 633 nm (or 670 to 690 nm for solid state) Scans the plate with red light in a raster pattern
and gives energy to the trapped electrons
X-ray interaction with a PSP screen
1
2
X-ray interactions with the screen phosphors causes an e- to excited
When e- return to groundstate visible light is emitted
CR Phosphor PlatesCR Phosphor Plates
ABSORPTION EMISSION
X-RAY
LIGHT
LASER STIMULATION
ELECTRONTRAP
ELECTRONTRAP
CR Reader ndash PSP plate
Stimulates the matrix of trapped E- by a RED OR ULTRAVIOLET laser light
Trapped E- energy is released in a form of VIOLETBLUE light
Violet light is captured by PMT ndash is amplified and converted into a digital signal
Sequence of CR imaging
PMT
Beam deflector
LaserSource
Light channeling guide
Plate translation Sub-scan direction
Laser beam Scan direction
Output Signal
Reference detec tor
Beam splitter
Cylindrical m irrorf-thetalens
Amplifier
ADC
To imageprocessor
How CR works
Released light is captured by a PMT (photo
multiplier tube) An ultrasensitive photomultiplier tube or CCD (charged couple device)
PSP light is amplified by the PMT or CCD
This light is sent to the analog to digital converter (ADC) To convert light to binary
PMT (photomultiplier tube) The intensity (brightness) of the light ndash
correlates to the density on the image
So lots of light will correlate to what size number amp what color on the image
The digital numeric values are stored in matrix form called pixels for display on a cathode ray tube (CRT) or printed on film
ERASING THE SCREEN ~50 of trapped electrons released during ldquoreadrdquo After image is recorded Plate is erased with high intensity white light and
re-used Erasing should be done after every exposure or
at minimum every 24 hours to avoid ghosting on future images
Basics of Digital Images
bull digital images are a (matrix) of pixel (picture element) values
Pixels Digital images are made of discrete picture
elements arranged in a matrix The size of the image is described in the binary number system
Modern imaging systems are at least 1024 x 1024
4096 x 4096 is being developed for digital radiography
Matrix = each cell corresponds to a specific location on the image
Pixel
Pixels
Digital Images ndash Bit Depth
bull Pixel values can be any bit depth (values from 0 to 1023)
bull Bit depth = or gray shades available for image display
bull Image contrast can be manipulated to stretched or contracted to alter the displayed contrast
bull Typically use ldquowindow widthrdquo and ldquowindow levelrdquo to alter displayed contrast and brightness
Digital - Grayscale
Bit depth Number of gray shades
available for display 8 bit 256 10 bit 1024 12 bit 4096 4 bit 16384
Display Bit Depth1 bit 6 bit 8 bit
2 shades 64 shades 256 shades
Computed Radiography As the plate is scanned ldquoreadrdquo data is collected
at a specific frequency = Sampling frequency
Spatial resolution determined by sampling frequency
With some systems the smaller IRrsquos have higher sampling frequencies amp more pixels per mm = more spatial resolution
Signal Loss (reducing image quality) Signal-to-Noise Ratio
Principle source of noise on the image is scatter radiation
Scattering of emitted light off screen
The efficiency of the photomultiplier tubes (PMTs) and photodiodes (PDs)
Improving Signal-to-Noise Ratio
Optical filter is used to prevent the longer-wavelength laser light affecting the image formation
Increasing exposure to IR Newer CR systems are better at reducing noise at lower exposure levels
Technique Selections
What are some factors that technologist must take into consideration when selecting a technique
What regulates that technologists to select appropriate techniques in FS CR amp DR
Screen Film
Self regulating system The receptor speed and film HampD curve defined
the proper exposure Achieving optimal OD guaranteed appropriate
exposure to the patient Over exposed = dark image Correct exposure = correct OD Under exposed = light image
Characteristic curveof radiographic film
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 15: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/15.jpg)
IMAGE CREATION
SAME RADIOGRAPHY EQUIPMENT USED
THE DIFFERENCE IS HOW IT IS CAPTURED
STORED VIEWED And POST -PROCESSED
General Overview CR
PSP cassette exposed by conventional x-ray equipment
Latent image generated as a matrix of trapped electrons in the PSP plate
CR BASICS
bull Eliminates the need for film as a recording storage amp viewing medium
bull PSP Plate ndash receiverbull Archive Manager ndash storagebull Monitor - Viewing
Digital
Radiography
DirectCapture
IndirectCapture
Direct-to-DigitalRadiography
(DDR)-Selenium
ComputedRadiography
(CR) - PSL
LaserScanningDigitizers
Direct-to-DigitalRadiographySilicon Scint
DDR CR
CR SYSTEM COMPONENTS
CASSETTES (phosphor plates) ID STATION IMAGE PREVIEW (QC)
STATION DIGITIZER VIEWING STATION
ID STATIONID STATION
CR Readers
AKA
CR Processors
Fuji Agfa Kodak
Computed Radiographic Readers
CR ndash PSP plate
photostimulable phosphor (PSP) plate
Exit photons energizes the PSP plate
The energy is stored in traps on plate (latent image)
PLATE scanned in CR READER
Imaging Plate (IP)
Contained in a cassette
Handled the same as SF cassettes
Processed more like daylight processor with no chemicals
IP has lead backing to reduce scatter
Imaging Plate Construction
A thin sheet of plastic
IPrsquos have several layersA protective layer This is a very thin tough
clear plastic that protects the phosphor layer A phosphor or active layer This is a layer of
photostimulable phosphor that ldquotrapsrdquo electrons during exposure
Active Layer - Crystals The materials that make up the PSP plate
are from the barium fluorohalide family
Barium fluorohalide chlorohalide or bromohalide crystals The most common crystal uses is barium fluorohalide with europium
Acquiring the Image
The remnant beam interacts with electrons in the barium fluorohalide crystals
This interaction stimulates or gives energy to electrons in the crystals allowing them to enter the conductive layer
The Conductuve layer is where they are
trapped in an area of the crystal known as the color or phosphor center
Acquiring the Image cont
This trapped signal will remain for hours even days although deterioration begins almost immediately IR should be processed as soon as possible
The trapped signal is never completely lost
Imaging Plate Construction
A reflective layer This is a layer that sends light in a forward direction when released in the cassette reader This layer may be black to reduce the spread of stimulating light and the escape of emitted light Some detail is lost in this process
Imaging Plate Construction Conductive layer This is a layer of material that
absorbs and reduces static electricity A color layer Newer plates may contain a color
layer located between the active layer and the support that absorbs the stimulating light but reflects emitted light
A support layer This is a semirigid material that gives the imaging sheet some strength
A backing layer This is a soft polymer that protects the back of the cassette
Cross section of a PSP screen
Needle PSP increase the absorption of x-rays and limit the spread of light emission
IP Design
Designed to optimize the intensity of light release (CE)
Enhance the absorption of x-rays (DQE)
Limit the spread of light emission for more detail
Photostimulable Luminescence When the cassette is put into the reader the
imaging plate is extracted and scanned With a helium laser beam or in more recent
systems solid-state laser diodes This beam about 100μm wide with a wavelength
of 633 nm (or 670 to 690 nm for solid state) Scans the plate with red light in a raster pattern
and gives energy to the trapped electrons
X-ray interaction with a PSP screen
1
2
X-ray interactions with the screen phosphors causes an e- to excited
When e- return to groundstate visible light is emitted
CR Phosphor PlatesCR Phosphor Plates
ABSORPTION EMISSION
X-RAY
LIGHT
LASER STIMULATION
ELECTRONTRAP
ELECTRONTRAP
CR Reader ndash PSP plate
Stimulates the matrix of trapped E- by a RED OR ULTRAVIOLET laser light
Trapped E- energy is released in a form of VIOLETBLUE light
Violet light is captured by PMT ndash is amplified and converted into a digital signal
Sequence of CR imaging
PMT
Beam deflector
LaserSource
Light channeling guide
Plate translation Sub-scan direction
Laser beam Scan direction
Output Signal
Reference detec tor
Beam splitter
Cylindrical m irrorf-thetalens
Amplifier
ADC
To imageprocessor
How CR works
Released light is captured by a PMT (photo
multiplier tube) An ultrasensitive photomultiplier tube or CCD (charged couple device)
PSP light is amplified by the PMT or CCD
This light is sent to the analog to digital converter (ADC) To convert light to binary
PMT (photomultiplier tube) The intensity (brightness) of the light ndash
correlates to the density on the image
So lots of light will correlate to what size number amp what color on the image
The digital numeric values are stored in matrix form called pixels for display on a cathode ray tube (CRT) or printed on film
ERASING THE SCREEN ~50 of trapped electrons released during ldquoreadrdquo After image is recorded Plate is erased with high intensity white light and
re-used Erasing should be done after every exposure or
at minimum every 24 hours to avoid ghosting on future images
Basics of Digital Images
bull digital images are a (matrix) of pixel (picture element) values
Pixels Digital images are made of discrete picture
elements arranged in a matrix The size of the image is described in the binary number system
Modern imaging systems are at least 1024 x 1024
4096 x 4096 is being developed for digital radiography
Matrix = each cell corresponds to a specific location on the image
Pixel
Pixels
Digital Images ndash Bit Depth
bull Pixel values can be any bit depth (values from 0 to 1023)
bull Bit depth = or gray shades available for image display
bull Image contrast can be manipulated to stretched or contracted to alter the displayed contrast
bull Typically use ldquowindow widthrdquo and ldquowindow levelrdquo to alter displayed contrast and brightness
Digital - Grayscale
Bit depth Number of gray shades
available for display 8 bit 256 10 bit 1024 12 bit 4096 4 bit 16384
Display Bit Depth1 bit 6 bit 8 bit
2 shades 64 shades 256 shades
Computed Radiography As the plate is scanned ldquoreadrdquo data is collected
at a specific frequency = Sampling frequency
Spatial resolution determined by sampling frequency
With some systems the smaller IRrsquos have higher sampling frequencies amp more pixels per mm = more spatial resolution
Signal Loss (reducing image quality) Signal-to-Noise Ratio
Principle source of noise on the image is scatter radiation
Scattering of emitted light off screen
The efficiency of the photomultiplier tubes (PMTs) and photodiodes (PDs)
Improving Signal-to-Noise Ratio
Optical filter is used to prevent the longer-wavelength laser light affecting the image formation
Increasing exposure to IR Newer CR systems are better at reducing noise at lower exposure levels
Technique Selections
What are some factors that technologist must take into consideration when selecting a technique
What regulates that technologists to select appropriate techniques in FS CR amp DR
Screen Film
Self regulating system The receptor speed and film HampD curve defined
the proper exposure Achieving optimal OD guaranteed appropriate
exposure to the patient Over exposed = dark image Correct exposure = correct OD Under exposed = light image
Characteristic curveof radiographic film
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 16: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/16.jpg)
General Overview CR
PSP cassette exposed by conventional x-ray equipment
Latent image generated as a matrix of trapped electrons in the PSP plate
CR BASICS
bull Eliminates the need for film as a recording storage amp viewing medium
bull PSP Plate ndash receiverbull Archive Manager ndash storagebull Monitor - Viewing
Digital
Radiography
DirectCapture
IndirectCapture
Direct-to-DigitalRadiography
(DDR)-Selenium
ComputedRadiography
(CR) - PSL
LaserScanningDigitizers
Direct-to-DigitalRadiographySilicon Scint
DDR CR
CR SYSTEM COMPONENTS
CASSETTES (phosphor plates) ID STATION IMAGE PREVIEW (QC)
STATION DIGITIZER VIEWING STATION
ID STATIONID STATION
CR Readers
AKA
CR Processors
Fuji Agfa Kodak
Computed Radiographic Readers
CR ndash PSP plate
photostimulable phosphor (PSP) plate
Exit photons energizes the PSP plate
The energy is stored in traps on plate (latent image)
PLATE scanned in CR READER
Imaging Plate (IP)
Contained in a cassette
Handled the same as SF cassettes
Processed more like daylight processor with no chemicals
IP has lead backing to reduce scatter
Imaging Plate Construction
A thin sheet of plastic
IPrsquos have several layersA protective layer This is a very thin tough
clear plastic that protects the phosphor layer A phosphor or active layer This is a layer of
photostimulable phosphor that ldquotrapsrdquo electrons during exposure
Active Layer - Crystals The materials that make up the PSP plate
are from the barium fluorohalide family
Barium fluorohalide chlorohalide or bromohalide crystals The most common crystal uses is barium fluorohalide with europium
Acquiring the Image
The remnant beam interacts with electrons in the barium fluorohalide crystals
This interaction stimulates or gives energy to electrons in the crystals allowing them to enter the conductive layer
The Conductuve layer is where they are
trapped in an area of the crystal known as the color or phosphor center
Acquiring the Image cont
This trapped signal will remain for hours even days although deterioration begins almost immediately IR should be processed as soon as possible
The trapped signal is never completely lost
Imaging Plate Construction
A reflective layer This is a layer that sends light in a forward direction when released in the cassette reader This layer may be black to reduce the spread of stimulating light and the escape of emitted light Some detail is lost in this process
Imaging Plate Construction Conductive layer This is a layer of material that
absorbs and reduces static electricity A color layer Newer plates may contain a color
layer located between the active layer and the support that absorbs the stimulating light but reflects emitted light
A support layer This is a semirigid material that gives the imaging sheet some strength
A backing layer This is a soft polymer that protects the back of the cassette
Cross section of a PSP screen
Needle PSP increase the absorption of x-rays and limit the spread of light emission
IP Design
Designed to optimize the intensity of light release (CE)
Enhance the absorption of x-rays (DQE)
Limit the spread of light emission for more detail
Photostimulable Luminescence When the cassette is put into the reader the
imaging plate is extracted and scanned With a helium laser beam or in more recent
systems solid-state laser diodes This beam about 100μm wide with a wavelength
of 633 nm (or 670 to 690 nm for solid state) Scans the plate with red light in a raster pattern
and gives energy to the trapped electrons
X-ray interaction with a PSP screen
1
2
X-ray interactions with the screen phosphors causes an e- to excited
When e- return to groundstate visible light is emitted
CR Phosphor PlatesCR Phosphor Plates
ABSORPTION EMISSION
X-RAY
LIGHT
LASER STIMULATION
ELECTRONTRAP
ELECTRONTRAP
CR Reader ndash PSP plate
Stimulates the matrix of trapped E- by a RED OR ULTRAVIOLET laser light
Trapped E- energy is released in a form of VIOLETBLUE light
Violet light is captured by PMT ndash is amplified and converted into a digital signal
Sequence of CR imaging
PMT
Beam deflector
LaserSource
Light channeling guide
Plate translation Sub-scan direction
Laser beam Scan direction
Output Signal
Reference detec tor
Beam splitter
Cylindrical m irrorf-thetalens
Amplifier
ADC
To imageprocessor
How CR works
Released light is captured by a PMT (photo
multiplier tube) An ultrasensitive photomultiplier tube or CCD (charged couple device)
PSP light is amplified by the PMT or CCD
This light is sent to the analog to digital converter (ADC) To convert light to binary
PMT (photomultiplier tube) The intensity (brightness) of the light ndash
correlates to the density on the image
So lots of light will correlate to what size number amp what color on the image
The digital numeric values are stored in matrix form called pixels for display on a cathode ray tube (CRT) or printed on film
ERASING THE SCREEN ~50 of trapped electrons released during ldquoreadrdquo After image is recorded Plate is erased with high intensity white light and
re-used Erasing should be done after every exposure or
at minimum every 24 hours to avoid ghosting on future images
Basics of Digital Images
bull digital images are a (matrix) of pixel (picture element) values
Pixels Digital images are made of discrete picture
elements arranged in a matrix The size of the image is described in the binary number system
Modern imaging systems are at least 1024 x 1024
4096 x 4096 is being developed for digital radiography
Matrix = each cell corresponds to a specific location on the image
Pixel
Pixels
Digital Images ndash Bit Depth
bull Pixel values can be any bit depth (values from 0 to 1023)
bull Bit depth = or gray shades available for image display
bull Image contrast can be manipulated to stretched or contracted to alter the displayed contrast
bull Typically use ldquowindow widthrdquo and ldquowindow levelrdquo to alter displayed contrast and brightness
Digital - Grayscale
Bit depth Number of gray shades
available for display 8 bit 256 10 bit 1024 12 bit 4096 4 bit 16384
Display Bit Depth1 bit 6 bit 8 bit
2 shades 64 shades 256 shades
Computed Radiography As the plate is scanned ldquoreadrdquo data is collected
at a specific frequency = Sampling frequency
Spatial resolution determined by sampling frequency
With some systems the smaller IRrsquos have higher sampling frequencies amp more pixels per mm = more spatial resolution
Signal Loss (reducing image quality) Signal-to-Noise Ratio
Principle source of noise on the image is scatter radiation
Scattering of emitted light off screen
The efficiency of the photomultiplier tubes (PMTs) and photodiodes (PDs)
Improving Signal-to-Noise Ratio
Optical filter is used to prevent the longer-wavelength laser light affecting the image formation
Increasing exposure to IR Newer CR systems are better at reducing noise at lower exposure levels
Technique Selections
What are some factors that technologist must take into consideration when selecting a technique
What regulates that technologists to select appropriate techniques in FS CR amp DR
Screen Film
Self regulating system The receptor speed and film HampD curve defined
the proper exposure Achieving optimal OD guaranteed appropriate
exposure to the patient Over exposed = dark image Correct exposure = correct OD Under exposed = light image
Characteristic curveof radiographic film
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 17: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/17.jpg)
CR BASICS
bull Eliminates the need for film as a recording storage amp viewing medium
bull PSP Plate ndash receiverbull Archive Manager ndash storagebull Monitor - Viewing
Digital
Radiography
DirectCapture
IndirectCapture
Direct-to-DigitalRadiography
(DDR)-Selenium
ComputedRadiography
(CR) - PSL
LaserScanningDigitizers
Direct-to-DigitalRadiographySilicon Scint
DDR CR
CR SYSTEM COMPONENTS
CASSETTES (phosphor plates) ID STATION IMAGE PREVIEW (QC)
STATION DIGITIZER VIEWING STATION
ID STATIONID STATION
CR Readers
AKA
CR Processors
Fuji Agfa Kodak
Computed Radiographic Readers
CR ndash PSP plate
photostimulable phosphor (PSP) plate
Exit photons energizes the PSP plate
The energy is stored in traps on plate (latent image)
PLATE scanned in CR READER
Imaging Plate (IP)
Contained in a cassette
Handled the same as SF cassettes
Processed more like daylight processor with no chemicals
IP has lead backing to reduce scatter
Imaging Plate Construction
A thin sheet of plastic
IPrsquos have several layersA protective layer This is a very thin tough
clear plastic that protects the phosphor layer A phosphor or active layer This is a layer of
photostimulable phosphor that ldquotrapsrdquo electrons during exposure
Active Layer - Crystals The materials that make up the PSP plate
are from the barium fluorohalide family
Barium fluorohalide chlorohalide or bromohalide crystals The most common crystal uses is barium fluorohalide with europium
Acquiring the Image
The remnant beam interacts with electrons in the barium fluorohalide crystals
This interaction stimulates or gives energy to electrons in the crystals allowing them to enter the conductive layer
The Conductuve layer is where they are
trapped in an area of the crystal known as the color or phosphor center
Acquiring the Image cont
This trapped signal will remain for hours even days although deterioration begins almost immediately IR should be processed as soon as possible
The trapped signal is never completely lost
Imaging Plate Construction
A reflective layer This is a layer that sends light in a forward direction when released in the cassette reader This layer may be black to reduce the spread of stimulating light and the escape of emitted light Some detail is lost in this process
Imaging Plate Construction Conductive layer This is a layer of material that
absorbs and reduces static electricity A color layer Newer plates may contain a color
layer located between the active layer and the support that absorbs the stimulating light but reflects emitted light
A support layer This is a semirigid material that gives the imaging sheet some strength
A backing layer This is a soft polymer that protects the back of the cassette
Cross section of a PSP screen
Needle PSP increase the absorption of x-rays and limit the spread of light emission
IP Design
Designed to optimize the intensity of light release (CE)
Enhance the absorption of x-rays (DQE)
Limit the spread of light emission for more detail
Photostimulable Luminescence When the cassette is put into the reader the
imaging plate is extracted and scanned With a helium laser beam or in more recent
systems solid-state laser diodes This beam about 100μm wide with a wavelength
of 633 nm (or 670 to 690 nm for solid state) Scans the plate with red light in a raster pattern
and gives energy to the trapped electrons
X-ray interaction with a PSP screen
1
2
X-ray interactions with the screen phosphors causes an e- to excited
When e- return to groundstate visible light is emitted
CR Phosphor PlatesCR Phosphor Plates
ABSORPTION EMISSION
X-RAY
LIGHT
LASER STIMULATION
ELECTRONTRAP
ELECTRONTRAP
CR Reader ndash PSP plate
Stimulates the matrix of trapped E- by a RED OR ULTRAVIOLET laser light
Trapped E- energy is released in a form of VIOLETBLUE light
Violet light is captured by PMT ndash is amplified and converted into a digital signal
Sequence of CR imaging
PMT
Beam deflector
LaserSource
Light channeling guide
Plate translation Sub-scan direction
Laser beam Scan direction
Output Signal
Reference detec tor
Beam splitter
Cylindrical m irrorf-thetalens
Amplifier
ADC
To imageprocessor
How CR works
Released light is captured by a PMT (photo
multiplier tube) An ultrasensitive photomultiplier tube or CCD (charged couple device)
PSP light is amplified by the PMT or CCD
This light is sent to the analog to digital converter (ADC) To convert light to binary
PMT (photomultiplier tube) The intensity (brightness) of the light ndash
correlates to the density on the image
So lots of light will correlate to what size number amp what color on the image
The digital numeric values are stored in matrix form called pixels for display on a cathode ray tube (CRT) or printed on film
ERASING THE SCREEN ~50 of trapped electrons released during ldquoreadrdquo After image is recorded Plate is erased with high intensity white light and
re-used Erasing should be done after every exposure or
at minimum every 24 hours to avoid ghosting on future images
Basics of Digital Images
bull digital images are a (matrix) of pixel (picture element) values
Pixels Digital images are made of discrete picture
elements arranged in a matrix The size of the image is described in the binary number system
Modern imaging systems are at least 1024 x 1024
4096 x 4096 is being developed for digital radiography
Matrix = each cell corresponds to a specific location on the image
Pixel
Pixels
Digital Images ndash Bit Depth
bull Pixel values can be any bit depth (values from 0 to 1023)
bull Bit depth = or gray shades available for image display
bull Image contrast can be manipulated to stretched or contracted to alter the displayed contrast
bull Typically use ldquowindow widthrdquo and ldquowindow levelrdquo to alter displayed contrast and brightness
Digital - Grayscale
Bit depth Number of gray shades
available for display 8 bit 256 10 bit 1024 12 bit 4096 4 bit 16384
Display Bit Depth1 bit 6 bit 8 bit
2 shades 64 shades 256 shades
Computed Radiography As the plate is scanned ldquoreadrdquo data is collected
at a specific frequency = Sampling frequency
Spatial resolution determined by sampling frequency
With some systems the smaller IRrsquos have higher sampling frequencies amp more pixels per mm = more spatial resolution
Signal Loss (reducing image quality) Signal-to-Noise Ratio
Principle source of noise on the image is scatter radiation
Scattering of emitted light off screen
The efficiency of the photomultiplier tubes (PMTs) and photodiodes (PDs)
Improving Signal-to-Noise Ratio
Optical filter is used to prevent the longer-wavelength laser light affecting the image formation
Increasing exposure to IR Newer CR systems are better at reducing noise at lower exposure levels
Technique Selections
What are some factors that technologist must take into consideration when selecting a technique
What regulates that technologists to select appropriate techniques in FS CR amp DR
Screen Film
Self regulating system The receptor speed and film HampD curve defined
the proper exposure Achieving optimal OD guaranteed appropriate
exposure to the patient Over exposed = dark image Correct exposure = correct OD Under exposed = light image
Characteristic curveof radiographic film
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 18: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/18.jpg)
Digital
Radiography
DirectCapture
IndirectCapture
Direct-to-DigitalRadiography
(DDR)-Selenium
ComputedRadiography
(CR) - PSL
LaserScanningDigitizers
Direct-to-DigitalRadiographySilicon Scint
DDR CR
CR SYSTEM COMPONENTS
CASSETTES (phosphor plates) ID STATION IMAGE PREVIEW (QC)
STATION DIGITIZER VIEWING STATION
ID STATIONID STATION
CR Readers
AKA
CR Processors
Fuji Agfa Kodak
Computed Radiographic Readers
CR ndash PSP plate
photostimulable phosphor (PSP) plate
Exit photons energizes the PSP plate
The energy is stored in traps on plate (latent image)
PLATE scanned in CR READER
Imaging Plate (IP)
Contained in a cassette
Handled the same as SF cassettes
Processed more like daylight processor with no chemicals
IP has lead backing to reduce scatter
Imaging Plate Construction
A thin sheet of plastic
IPrsquos have several layersA protective layer This is a very thin tough
clear plastic that protects the phosphor layer A phosphor or active layer This is a layer of
photostimulable phosphor that ldquotrapsrdquo electrons during exposure
Active Layer - Crystals The materials that make up the PSP plate
are from the barium fluorohalide family
Barium fluorohalide chlorohalide or bromohalide crystals The most common crystal uses is barium fluorohalide with europium
Acquiring the Image
The remnant beam interacts with electrons in the barium fluorohalide crystals
This interaction stimulates or gives energy to electrons in the crystals allowing them to enter the conductive layer
The Conductuve layer is where they are
trapped in an area of the crystal known as the color or phosphor center
Acquiring the Image cont
This trapped signal will remain for hours even days although deterioration begins almost immediately IR should be processed as soon as possible
The trapped signal is never completely lost
Imaging Plate Construction
A reflective layer This is a layer that sends light in a forward direction when released in the cassette reader This layer may be black to reduce the spread of stimulating light and the escape of emitted light Some detail is lost in this process
Imaging Plate Construction Conductive layer This is a layer of material that
absorbs and reduces static electricity A color layer Newer plates may contain a color
layer located between the active layer and the support that absorbs the stimulating light but reflects emitted light
A support layer This is a semirigid material that gives the imaging sheet some strength
A backing layer This is a soft polymer that protects the back of the cassette
Cross section of a PSP screen
Needle PSP increase the absorption of x-rays and limit the spread of light emission
IP Design
Designed to optimize the intensity of light release (CE)
Enhance the absorption of x-rays (DQE)
Limit the spread of light emission for more detail
Photostimulable Luminescence When the cassette is put into the reader the
imaging plate is extracted and scanned With a helium laser beam or in more recent
systems solid-state laser diodes This beam about 100μm wide with a wavelength
of 633 nm (or 670 to 690 nm for solid state) Scans the plate with red light in a raster pattern
and gives energy to the trapped electrons
X-ray interaction with a PSP screen
1
2
X-ray interactions with the screen phosphors causes an e- to excited
When e- return to groundstate visible light is emitted
CR Phosphor PlatesCR Phosphor Plates
ABSORPTION EMISSION
X-RAY
LIGHT
LASER STIMULATION
ELECTRONTRAP
ELECTRONTRAP
CR Reader ndash PSP plate
Stimulates the matrix of trapped E- by a RED OR ULTRAVIOLET laser light
Trapped E- energy is released in a form of VIOLETBLUE light
Violet light is captured by PMT ndash is amplified and converted into a digital signal
Sequence of CR imaging
PMT
Beam deflector
LaserSource
Light channeling guide
Plate translation Sub-scan direction
Laser beam Scan direction
Output Signal
Reference detec tor
Beam splitter
Cylindrical m irrorf-thetalens
Amplifier
ADC
To imageprocessor
How CR works
Released light is captured by a PMT (photo
multiplier tube) An ultrasensitive photomultiplier tube or CCD (charged couple device)
PSP light is amplified by the PMT or CCD
This light is sent to the analog to digital converter (ADC) To convert light to binary
PMT (photomultiplier tube) The intensity (brightness) of the light ndash
correlates to the density on the image
So lots of light will correlate to what size number amp what color on the image
The digital numeric values are stored in matrix form called pixels for display on a cathode ray tube (CRT) or printed on film
ERASING THE SCREEN ~50 of trapped electrons released during ldquoreadrdquo After image is recorded Plate is erased with high intensity white light and
re-used Erasing should be done after every exposure or
at minimum every 24 hours to avoid ghosting on future images
Basics of Digital Images
bull digital images are a (matrix) of pixel (picture element) values
Pixels Digital images are made of discrete picture
elements arranged in a matrix The size of the image is described in the binary number system
Modern imaging systems are at least 1024 x 1024
4096 x 4096 is being developed for digital radiography
Matrix = each cell corresponds to a specific location on the image
Pixel
Pixels
Digital Images ndash Bit Depth
bull Pixel values can be any bit depth (values from 0 to 1023)
bull Bit depth = or gray shades available for image display
bull Image contrast can be manipulated to stretched or contracted to alter the displayed contrast
bull Typically use ldquowindow widthrdquo and ldquowindow levelrdquo to alter displayed contrast and brightness
Digital - Grayscale
Bit depth Number of gray shades
available for display 8 bit 256 10 bit 1024 12 bit 4096 4 bit 16384
Display Bit Depth1 bit 6 bit 8 bit
2 shades 64 shades 256 shades
Computed Radiography As the plate is scanned ldquoreadrdquo data is collected
at a specific frequency = Sampling frequency
Spatial resolution determined by sampling frequency
With some systems the smaller IRrsquos have higher sampling frequencies amp more pixels per mm = more spatial resolution
Signal Loss (reducing image quality) Signal-to-Noise Ratio
Principle source of noise on the image is scatter radiation
Scattering of emitted light off screen
The efficiency of the photomultiplier tubes (PMTs) and photodiodes (PDs)
Improving Signal-to-Noise Ratio
Optical filter is used to prevent the longer-wavelength laser light affecting the image formation
Increasing exposure to IR Newer CR systems are better at reducing noise at lower exposure levels
Technique Selections
What are some factors that technologist must take into consideration when selecting a technique
What regulates that technologists to select appropriate techniques in FS CR amp DR
Screen Film
Self regulating system The receptor speed and film HampD curve defined
the proper exposure Achieving optimal OD guaranteed appropriate
exposure to the patient Over exposed = dark image Correct exposure = correct OD Under exposed = light image
Characteristic curveof radiographic film
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 19: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/19.jpg)
CR SYSTEM COMPONENTS
CASSETTES (phosphor plates) ID STATION IMAGE PREVIEW (QC)
STATION DIGITIZER VIEWING STATION
ID STATIONID STATION
CR Readers
AKA
CR Processors
Fuji Agfa Kodak
Computed Radiographic Readers
CR ndash PSP plate
photostimulable phosphor (PSP) plate
Exit photons energizes the PSP plate
The energy is stored in traps on plate (latent image)
PLATE scanned in CR READER
Imaging Plate (IP)
Contained in a cassette
Handled the same as SF cassettes
Processed more like daylight processor with no chemicals
IP has lead backing to reduce scatter
Imaging Plate Construction
A thin sheet of plastic
IPrsquos have several layersA protective layer This is a very thin tough
clear plastic that protects the phosphor layer A phosphor or active layer This is a layer of
photostimulable phosphor that ldquotrapsrdquo electrons during exposure
Active Layer - Crystals The materials that make up the PSP plate
are from the barium fluorohalide family
Barium fluorohalide chlorohalide or bromohalide crystals The most common crystal uses is barium fluorohalide with europium
Acquiring the Image
The remnant beam interacts with electrons in the barium fluorohalide crystals
This interaction stimulates or gives energy to electrons in the crystals allowing them to enter the conductive layer
The Conductuve layer is where they are
trapped in an area of the crystal known as the color or phosphor center
Acquiring the Image cont
This trapped signal will remain for hours even days although deterioration begins almost immediately IR should be processed as soon as possible
The trapped signal is never completely lost
Imaging Plate Construction
A reflective layer This is a layer that sends light in a forward direction when released in the cassette reader This layer may be black to reduce the spread of stimulating light and the escape of emitted light Some detail is lost in this process
Imaging Plate Construction Conductive layer This is a layer of material that
absorbs and reduces static electricity A color layer Newer plates may contain a color
layer located between the active layer and the support that absorbs the stimulating light but reflects emitted light
A support layer This is a semirigid material that gives the imaging sheet some strength
A backing layer This is a soft polymer that protects the back of the cassette
Cross section of a PSP screen
Needle PSP increase the absorption of x-rays and limit the spread of light emission
IP Design
Designed to optimize the intensity of light release (CE)
Enhance the absorption of x-rays (DQE)
Limit the spread of light emission for more detail
Photostimulable Luminescence When the cassette is put into the reader the
imaging plate is extracted and scanned With a helium laser beam or in more recent
systems solid-state laser diodes This beam about 100μm wide with a wavelength
of 633 nm (or 670 to 690 nm for solid state) Scans the plate with red light in a raster pattern
and gives energy to the trapped electrons
X-ray interaction with a PSP screen
1
2
X-ray interactions with the screen phosphors causes an e- to excited
When e- return to groundstate visible light is emitted
CR Phosphor PlatesCR Phosphor Plates
ABSORPTION EMISSION
X-RAY
LIGHT
LASER STIMULATION
ELECTRONTRAP
ELECTRONTRAP
CR Reader ndash PSP plate
Stimulates the matrix of trapped E- by a RED OR ULTRAVIOLET laser light
Trapped E- energy is released in a form of VIOLETBLUE light
Violet light is captured by PMT ndash is amplified and converted into a digital signal
Sequence of CR imaging
PMT
Beam deflector
LaserSource
Light channeling guide
Plate translation Sub-scan direction
Laser beam Scan direction
Output Signal
Reference detec tor
Beam splitter
Cylindrical m irrorf-thetalens
Amplifier
ADC
To imageprocessor
How CR works
Released light is captured by a PMT (photo
multiplier tube) An ultrasensitive photomultiplier tube or CCD (charged couple device)
PSP light is amplified by the PMT or CCD
This light is sent to the analog to digital converter (ADC) To convert light to binary
PMT (photomultiplier tube) The intensity (brightness) of the light ndash
correlates to the density on the image
So lots of light will correlate to what size number amp what color on the image
The digital numeric values are stored in matrix form called pixels for display on a cathode ray tube (CRT) or printed on film
ERASING THE SCREEN ~50 of trapped electrons released during ldquoreadrdquo After image is recorded Plate is erased with high intensity white light and
re-used Erasing should be done after every exposure or
at minimum every 24 hours to avoid ghosting on future images
Basics of Digital Images
bull digital images are a (matrix) of pixel (picture element) values
Pixels Digital images are made of discrete picture
elements arranged in a matrix The size of the image is described in the binary number system
Modern imaging systems are at least 1024 x 1024
4096 x 4096 is being developed for digital radiography
Matrix = each cell corresponds to a specific location on the image
Pixel
Pixels
Digital Images ndash Bit Depth
bull Pixel values can be any bit depth (values from 0 to 1023)
bull Bit depth = or gray shades available for image display
bull Image contrast can be manipulated to stretched or contracted to alter the displayed contrast
bull Typically use ldquowindow widthrdquo and ldquowindow levelrdquo to alter displayed contrast and brightness
Digital - Grayscale
Bit depth Number of gray shades
available for display 8 bit 256 10 bit 1024 12 bit 4096 4 bit 16384
Display Bit Depth1 bit 6 bit 8 bit
2 shades 64 shades 256 shades
Computed Radiography As the plate is scanned ldquoreadrdquo data is collected
at a specific frequency = Sampling frequency
Spatial resolution determined by sampling frequency
With some systems the smaller IRrsquos have higher sampling frequencies amp more pixels per mm = more spatial resolution
Signal Loss (reducing image quality) Signal-to-Noise Ratio
Principle source of noise on the image is scatter radiation
Scattering of emitted light off screen
The efficiency of the photomultiplier tubes (PMTs) and photodiodes (PDs)
Improving Signal-to-Noise Ratio
Optical filter is used to prevent the longer-wavelength laser light affecting the image formation
Increasing exposure to IR Newer CR systems are better at reducing noise at lower exposure levels
Technique Selections
What are some factors that technologist must take into consideration when selecting a technique
What regulates that technologists to select appropriate techniques in FS CR amp DR
Screen Film
Self regulating system The receptor speed and film HampD curve defined
the proper exposure Achieving optimal OD guaranteed appropriate
exposure to the patient Over exposed = dark image Correct exposure = correct OD Under exposed = light image
Characteristic curveof radiographic film
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 20: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/20.jpg)
ID STATIONID STATION
CR Readers
AKA
CR Processors
Fuji Agfa Kodak
Computed Radiographic Readers
CR ndash PSP plate
photostimulable phosphor (PSP) plate
Exit photons energizes the PSP plate
The energy is stored in traps on plate (latent image)
PLATE scanned in CR READER
Imaging Plate (IP)
Contained in a cassette
Handled the same as SF cassettes
Processed more like daylight processor with no chemicals
IP has lead backing to reduce scatter
Imaging Plate Construction
A thin sheet of plastic
IPrsquos have several layersA protective layer This is a very thin tough
clear plastic that protects the phosphor layer A phosphor or active layer This is a layer of
photostimulable phosphor that ldquotrapsrdquo electrons during exposure
Active Layer - Crystals The materials that make up the PSP plate
are from the barium fluorohalide family
Barium fluorohalide chlorohalide or bromohalide crystals The most common crystal uses is barium fluorohalide with europium
Acquiring the Image
The remnant beam interacts with electrons in the barium fluorohalide crystals
This interaction stimulates or gives energy to electrons in the crystals allowing them to enter the conductive layer
The Conductuve layer is where they are
trapped in an area of the crystal known as the color or phosphor center
Acquiring the Image cont
This trapped signal will remain for hours even days although deterioration begins almost immediately IR should be processed as soon as possible
The trapped signal is never completely lost
Imaging Plate Construction
A reflective layer This is a layer that sends light in a forward direction when released in the cassette reader This layer may be black to reduce the spread of stimulating light and the escape of emitted light Some detail is lost in this process
Imaging Plate Construction Conductive layer This is a layer of material that
absorbs and reduces static electricity A color layer Newer plates may contain a color
layer located between the active layer and the support that absorbs the stimulating light but reflects emitted light
A support layer This is a semirigid material that gives the imaging sheet some strength
A backing layer This is a soft polymer that protects the back of the cassette
Cross section of a PSP screen
Needle PSP increase the absorption of x-rays and limit the spread of light emission
IP Design
Designed to optimize the intensity of light release (CE)
Enhance the absorption of x-rays (DQE)
Limit the spread of light emission for more detail
Photostimulable Luminescence When the cassette is put into the reader the
imaging plate is extracted and scanned With a helium laser beam or in more recent
systems solid-state laser diodes This beam about 100μm wide with a wavelength
of 633 nm (or 670 to 690 nm for solid state) Scans the plate with red light in a raster pattern
and gives energy to the trapped electrons
X-ray interaction with a PSP screen
1
2
X-ray interactions with the screen phosphors causes an e- to excited
When e- return to groundstate visible light is emitted
CR Phosphor PlatesCR Phosphor Plates
ABSORPTION EMISSION
X-RAY
LIGHT
LASER STIMULATION
ELECTRONTRAP
ELECTRONTRAP
CR Reader ndash PSP plate
Stimulates the matrix of trapped E- by a RED OR ULTRAVIOLET laser light
Trapped E- energy is released in a form of VIOLETBLUE light
Violet light is captured by PMT ndash is amplified and converted into a digital signal
Sequence of CR imaging
PMT
Beam deflector
LaserSource
Light channeling guide
Plate translation Sub-scan direction
Laser beam Scan direction
Output Signal
Reference detec tor
Beam splitter
Cylindrical m irrorf-thetalens
Amplifier
ADC
To imageprocessor
How CR works
Released light is captured by a PMT (photo
multiplier tube) An ultrasensitive photomultiplier tube or CCD (charged couple device)
PSP light is amplified by the PMT or CCD
This light is sent to the analog to digital converter (ADC) To convert light to binary
PMT (photomultiplier tube) The intensity (brightness) of the light ndash
correlates to the density on the image
So lots of light will correlate to what size number amp what color on the image
The digital numeric values are stored in matrix form called pixels for display on a cathode ray tube (CRT) or printed on film
ERASING THE SCREEN ~50 of trapped electrons released during ldquoreadrdquo After image is recorded Plate is erased with high intensity white light and
re-used Erasing should be done after every exposure or
at minimum every 24 hours to avoid ghosting on future images
Basics of Digital Images
bull digital images are a (matrix) of pixel (picture element) values
Pixels Digital images are made of discrete picture
elements arranged in a matrix The size of the image is described in the binary number system
Modern imaging systems are at least 1024 x 1024
4096 x 4096 is being developed for digital radiography
Matrix = each cell corresponds to a specific location on the image
Pixel
Pixels
Digital Images ndash Bit Depth
bull Pixel values can be any bit depth (values from 0 to 1023)
bull Bit depth = or gray shades available for image display
bull Image contrast can be manipulated to stretched or contracted to alter the displayed contrast
bull Typically use ldquowindow widthrdquo and ldquowindow levelrdquo to alter displayed contrast and brightness
Digital - Grayscale
Bit depth Number of gray shades
available for display 8 bit 256 10 bit 1024 12 bit 4096 4 bit 16384
Display Bit Depth1 bit 6 bit 8 bit
2 shades 64 shades 256 shades
Computed Radiography As the plate is scanned ldquoreadrdquo data is collected
at a specific frequency = Sampling frequency
Spatial resolution determined by sampling frequency
With some systems the smaller IRrsquos have higher sampling frequencies amp more pixels per mm = more spatial resolution
Signal Loss (reducing image quality) Signal-to-Noise Ratio
Principle source of noise on the image is scatter radiation
Scattering of emitted light off screen
The efficiency of the photomultiplier tubes (PMTs) and photodiodes (PDs)
Improving Signal-to-Noise Ratio
Optical filter is used to prevent the longer-wavelength laser light affecting the image formation
Increasing exposure to IR Newer CR systems are better at reducing noise at lower exposure levels
Technique Selections
What are some factors that technologist must take into consideration when selecting a technique
What regulates that technologists to select appropriate techniques in FS CR amp DR
Screen Film
Self regulating system The receptor speed and film HampD curve defined
the proper exposure Achieving optimal OD guaranteed appropriate
exposure to the patient Over exposed = dark image Correct exposure = correct OD Under exposed = light image
Characteristic curveof radiographic film
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 21: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/21.jpg)
CR Readers
AKA
CR Processors
Fuji Agfa Kodak
Computed Radiographic Readers
CR ndash PSP plate
photostimulable phosphor (PSP) plate
Exit photons energizes the PSP plate
The energy is stored in traps on plate (latent image)
PLATE scanned in CR READER
Imaging Plate (IP)
Contained in a cassette
Handled the same as SF cassettes
Processed more like daylight processor with no chemicals
IP has lead backing to reduce scatter
Imaging Plate Construction
A thin sheet of plastic
IPrsquos have several layersA protective layer This is a very thin tough
clear plastic that protects the phosphor layer A phosphor or active layer This is a layer of
photostimulable phosphor that ldquotrapsrdquo electrons during exposure
Active Layer - Crystals The materials that make up the PSP plate
are from the barium fluorohalide family
Barium fluorohalide chlorohalide or bromohalide crystals The most common crystal uses is barium fluorohalide with europium
Acquiring the Image
The remnant beam interacts with electrons in the barium fluorohalide crystals
This interaction stimulates or gives energy to electrons in the crystals allowing them to enter the conductive layer
The Conductuve layer is where they are
trapped in an area of the crystal known as the color or phosphor center
Acquiring the Image cont
This trapped signal will remain for hours even days although deterioration begins almost immediately IR should be processed as soon as possible
The trapped signal is never completely lost
Imaging Plate Construction
A reflective layer This is a layer that sends light in a forward direction when released in the cassette reader This layer may be black to reduce the spread of stimulating light and the escape of emitted light Some detail is lost in this process
Imaging Plate Construction Conductive layer This is a layer of material that
absorbs and reduces static electricity A color layer Newer plates may contain a color
layer located between the active layer and the support that absorbs the stimulating light but reflects emitted light
A support layer This is a semirigid material that gives the imaging sheet some strength
A backing layer This is a soft polymer that protects the back of the cassette
Cross section of a PSP screen
Needle PSP increase the absorption of x-rays and limit the spread of light emission
IP Design
Designed to optimize the intensity of light release (CE)
Enhance the absorption of x-rays (DQE)
Limit the spread of light emission for more detail
Photostimulable Luminescence When the cassette is put into the reader the
imaging plate is extracted and scanned With a helium laser beam or in more recent
systems solid-state laser diodes This beam about 100μm wide with a wavelength
of 633 nm (or 670 to 690 nm for solid state) Scans the plate with red light in a raster pattern
and gives energy to the trapped electrons
X-ray interaction with a PSP screen
1
2
X-ray interactions with the screen phosphors causes an e- to excited
When e- return to groundstate visible light is emitted
CR Phosphor PlatesCR Phosphor Plates
ABSORPTION EMISSION
X-RAY
LIGHT
LASER STIMULATION
ELECTRONTRAP
ELECTRONTRAP
CR Reader ndash PSP plate
Stimulates the matrix of trapped E- by a RED OR ULTRAVIOLET laser light
Trapped E- energy is released in a form of VIOLETBLUE light
Violet light is captured by PMT ndash is amplified and converted into a digital signal
Sequence of CR imaging
PMT
Beam deflector
LaserSource
Light channeling guide
Plate translation Sub-scan direction
Laser beam Scan direction
Output Signal
Reference detec tor
Beam splitter
Cylindrical m irrorf-thetalens
Amplifier
ADC
To imageprocessor
How CR works
Released light is captured by a PMT (photo
multiplier tube) An ultrasensitive photomultiplier tube or CCD (charged couple device)
PSP light is amplified by the PMT or CCD
This light is sent to the analog to digital converter (ADC) To convert light to binary
PMT (photomultiplier tube) The intensity (brightness) of the light ndash
correlates to the density on the image
So lots of light will correlate to what size number amp what color on the image
The digital numeric values are stored in matrix form called pixels for display on a cathode ray tube (CRT) or printed on film
ERASING THE SCREEN ~50 of trapped electrons released during ldquoreadrdquo After image is recorded Plate is erased with high intensity white light and
re-used Erasing should be done after every exposure or
at minimum every 24 hours to avoid ghosting on future images
Basics of Digital Images
bull digital images are a (matrix) of pixel (picture element) values
Pixels Digital images are made of discrete picture
elements arranged in a matrix The size of the image is described in the binary number system
Modern imaging systems are at least 1024 x 1024
4096 x 4096 is being developed for digital radiography
Matrix = each cell corresponds to a specific location on the image
Pixel
Pixels
Digital Images ndash Bit Depth
bull Pixel values can be any bit depth (values from 0 to 1023)
bull Bit depth = or gray shades available for image display
bull Image contrast can be manipulated to stretched or contracted to alter the displayed contrast
bull Typically use ldquowindow widthrdquo and ldquowindow levelrdquo to alter displayed contrast and brightness
Digital - Grayscale
Bit depth Number of gray shades
available for display 8 bit 256 10 bit 1024 12 bit 4096 4 bit 16384
Display Bit Depth1 bit 6 bit 8 bit
2 shades 64 shades 256 shades
Computed Radiography As the plate is scanned ldquoreadrdquo data is collected
at a specific frequency = Sampling frequency
Spatial resolution determined by sampling frequency
With some systems the smaller IRrsquos have higher sampling frequencies amp more pixels per mm = more spatial resolution
Signal Loss (reducing image quality) Signal-to-Noise Ratio
Principle source of noise on the image is scatter radiation
Scattering of emitted light off screen
The efficiency of the photomultiplier tubes (PMTs) and photodiodes (PDs)
Improving Signal-to-Noise Ratio
Optical filter is used to prevent the longer-wavelength laser light affecting the image formation
Increasing exposure to IR Newer CR systems are better at reducing noise at lower exposure levels
Technique Selections
What are some factors that technologist must take into consideration when selecting a technique
What regulates that technologists to select appropriate techniques in FS CR amp DR
Screen Film
Self regulating system The receptor speed and film HampD curve defined
the proper exposure Achieving optimal OD guaranteed appropriate
exposure to the patient Over exposed = dark image Correct exposure = correct OD Under exposed = light image
Characteristic curveof radiographic film
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 22: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/22.jpg)
Fuji Agfa Kodak
Computed Radiographic Readers
CR ndash PSP plate
photostimulable phosphor (PSP) plate
Exit photons energizes the PSP plate
The energy is stored in traps on plate (latent image)
PLATE scanned in CR READER
Imaging Plate (IP)
Contained in a cassette
Handled the same as SF cassettes
Processed more like daylight processor with no chemicals
IP has lead backing to reduce scatter
Imaging Plate Construction
A thin sheet of plastic
IPrsquos have several layersA protective layer This is a very thin tough
clear plastic that protects the phosphor layer A phosphor or active layer This is a layer of
photostimulable phosphor that ldquotrapsrdquo electrons during exposure
Active Layer - Crystals The materials that make up the PSP plate
are from the barium fluorohalide family
Barium fluorohalide chlorohalide or bromohalide crystals The most common crystal uses is barium fluorohalide with europium
Acquiring the Image
The remnant beam interacts with electrons in the barium fluorohalide crystals
This interaction stimulates or gives energy to electrons in the crystals allowing them to enter the conductive layer
The Conductuve layer is where they are
trapped in an area of the crystal known as the color or phosphor center
Acquiring the Image cont
This trapped signal will remain for hours even days although deterioration begins almost immediately IR should be processed as soon as possible
The trapped signal is never completely lost
Imaging Plate Construction
A reflective layer This is a layer that sends light in a forward direction when released in the cassette reader This layer may be black to reduce the spread of stimulating light and the escape of emitted light Some detail is lost in this process
Imaging Plate Construction Conductive layer This is a layer of material that
absorbs and reduces static electricity A color layer Newer plates may contain a color
layer located between the active layer and the support that absorbs the stimulating light but reflects emitted light
A support layer This is a semirigid material that gives the imaging sheet some strength
A backing layer This is a soft polymer that protects the back of the cassette
Cross section of a PSP screen
Needle PSP increase the absorption of x-rays and limit the spread of light emission
IP Design
Designed to optimize the intensity of light release (CE)
Enhance the absorption of x-rays (DQE)
Limit the spread of light emission for more detail
Photostimulable Luminescence When the cassette is put into the reader the
imaging plate is extracted and scanned With a helium laser beam or in more recent
systems solid-state laser diodes This beam about 100μm wide with a wavelength
of 633 nm (or 670 to 690 nm for solid state) Scans the plate with red light in a raster pattern
and gives energy to the trapped electrons
X-ray interaction with a PSP screen
1
2
X-ray interactions with the screen phosphors causes an e- to excited
When e- return to groundstate visible light is emitted
CR Phosphor PlatesCR Phosphor Plates
ABSORPTION EMISSION
X-RAY
LIGHT
LASER STIMULATION
ELECTRONTRAP
ELECTRONTRAP
CR Reader ndash PSP plate
Stimulates the matrix of trapped E- by a RED OR ULTRAVIOLET laser light
Trapped E- energy is released in a form of VIOLETBLUE light
Violet light is captured by PMT ndash is amplified and converted into a digital signal
Sequence of CR imaging
PMT
Beam deflector
LaserSource
Light channeling guide
Plate translation Sub-scan direction
Laser beam Scan direction
Output Signal
Reference detec tor
Beam splitter
Cylindrical m irrorf-thetalens
Amplifier
ADC
To imageprocessor
How CR works
Released light is captured by a PMT (photo
multiplier tube) An ultrasensitive photomultiplier tube or CCD (charged couple device)
PSP light is amplified by the PMT or CCD
This light is sent to the analog to digital converter (ADC) To convert light to binary
PMT (photomultiplier tube) The intensity (brightness) of the light ndash
correlates to the density on the image
So lots of light will correlate to what size number amp what color on the image
The digital numeric values are stored in matrix form called pixels for display on a cathode ray tube (CRT) or printed on film
ERASING THE SCREEN ~50 of trapped electrons released during ldquoreadrdquo After image is recorded Plate is erased with high intensity white light and
re-used Erasing should be done after every exposure or
at minimum every 24 hours to avoid ghosting on future images
Basics of Digital Images
bull digital images are a (matrix) of pixel (picture element) values
Pixels Digital images are made of discrete picture
elements arranged in a matrix The size of the image is described in the binary number system
Modern imaging systems are at least 1024 x 1024
4096 x 4096 is being developed for digital radiography
Matrix = each cell corresponds to a specific location on the image
Pixel
Pixels
Digital Images ndash Bit Depth
bull Pixel values can be any bit depth (values from 0 to 1023)
bull Bit depth = or gray shades available for image display
bull Image contrast can be manipulated to stretched or contracted to alter the displayed contrast
bull Typically use ldquowindow widthrdquo and ldquowindow levelrdquo to alter displayed contrast and brightness
Digital - Grayscale
Bit depth Number of gray shades
available for display 8 bit 256 10 bit 1024 12 bit 4096 4 bit 16384
Display Bit Depth1 bit 6 bit 8 bit
2 shades 64 shades 256 shades
Computed Radiography As the plate is scanned ldquoreadrdquo data is collected
at a specific frequency = Sampling frequency
Spatial resolution determined by sampling frequency
With some systems the smaller IRrsquos have higher sampling frequencies amp more pixels per mm = more spatial resolution
Signal Loss (reducing image quality) Signal-to-Noise Ratio
Principle source of noise on the image is scatter radiation
Scattering of emitted light off screen
The efficiency of the photomultiplier tubes (PMTs) and photodiodes (PDs)
Improving Signal-to-Noise Ratio
Optical filter is used to prevent the longer-wavelength laser light affecting the image formation
Increasing exposure to IR Newer CR systems are better at reducing noise at lower exposure levels
Technique Selections
What are some factors that technologist must take into consideration when selecting a technique
What regulates that technologists to select appropriate techniques in FS CR amp DR
Screen Film
Self regulating system The receptor speed and film HampD curve defined
the proper exposure Achieving optimal OD guaranteed appropriate
exposure to the patient Over exposed = dark image Correct exposure = correct OD Under exposed = light image
Characteristic curveof radiographic film
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 23: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/23.jpg)
CR ndash PSP plate
photostimulable phosphor (PSP) plate
Exit photons energizes the PSP plate
The energy is stored in traps on plate (latent image)
PLATE scanned in CR READER
Imaging Plate (IP)
Contained in a cassette
Handled the same as SF cassettes
Processed more like daylight processor with no chemicals
IP has lead backing to reduce scatter
Imaging Plate Construction
A thin sheet of plastic
IPrsquos have several layersA protective layer This is a very thin tough
clear plastic that protects the phosphor layer A phosphor or active layer This is a layer of
photostimulable phosphor that ldquotrapsrdquo electrons during exposure
Active Layer - Crystals The materials that make up the PSP plate
are from the barium fluorohalide family
Barium fluorohalide chlorohalide or bromohalide crystals The most common crystal uses is barium fluorohalide with europium
Acquiring the Image
The remnant beam interacts with electrons in the barium fluorohalide crystals
This interaction stimulates or gives energy to electrons in the crystals allowing them to enter the conductive layer
The Conductuve layer is where they are
trapped in an area of the crystal known as the color or phosphor center
Acquiring the Image cont
This trapped signal will remain for hours even days although deterioration begins almost immediately IR should be processed as soon as possible
The trapped signal is never completely lost
Imaging Plate Construction
A reflective layer This is a layer that sends light in a forward direction when released in the cassette reader This layer may be black to reduce the spread of stimulating light and the escape of emitted light Some detail is lost in this process
Imaging Plate Construction Conductive layer This is a layer of material that
absorbs and reduces static electricity A color layer Newer plates may contain a color
layer located between the active layer and the support that absorbs the stimulating light but reflects emitted light
A support layer This is a semirigid material that gives the imaging sheet some strength
A backing layer This is a soft polymer that protects the back of the cassette
Cross section of a PSP screen
Needle PSP increase the absorption of x-rays and limit the spread of light emission
IP Design
Designed to optimize the intensity of light release (CE)
Enhance the absorption of x-rays (DQE)
Limit the spread of light emission for more detail
Photostimulable Luminescence When the cassette is put into the reader the
imaging plate is extracted and scanned With a helium laser beam or in more recent
systems solid-state laser diodes This beam about 100μm wide with a wavelength
of 633 nm (or 670 to 690 nm for solid state) Scans the plate with red light in a raster pattern
and gives energy to the trapped electrons
X-ray interaction with a PSP screen
1
2
X-ray interactions with the screen phosphors causes an e- to excited
When e- return to groundstate visible light is emitted
CR Phosphor PlatesCR Phosphor Plates
ABSORPTION EMISSION
X-RAY
LIGHT
LASER STIMULATION
ELECTRONTRAP
ELECTRONTRAP
CR Reader ndash PSP plate
Stimulates the matrix of trapped E- by a RED OR ULTRAVIOLET laser light
Trapped E- energy is released in a form of VIOLETBLUE light
Violet light is captured by PMT ndash is amplified and converted into a digital signal
Sequence of CR imaging
PMT
Beam deflector
LaserSource
Light channeling guide
Plate translation Sub-scan direction
Laser beam Scan direction
Output Signal
Reference detec tor
Beam splitter
Cylindrical m irrorf-thetalens
Amplifier
ADC
To imageprocessor
How CR works
Released light is captured by a PMT (photo
multiplier tube) An ultrasensitive photomultiplier tube or CCD (charged couple device)
PSP light is amplified by the PMT or CCD
This light is sent to the analog to digital converter (ADC) To convert light to binary
PMT (photomultiplier tube) The intensity (brightness) of the light ndash
correlates to the density on the image
So lots of light will correlate to what size number amp what color on the image
The digital numeric values are stored in matrix form called pixels for display on a cathode ray tube (CRT) or printed on film
ERASING THE SCREEN ~50 of trapped electrons released during ldquoreadrdquo After image is recorded Plate is erased with high intensity white light and
re-used Erasing should be done after every exposure or
at minimum every 24 hours to avoid ghosting on future images
Basics of Digital Images
bull digital images are a (matrix) of pixel (picture element) values
Pixels Digital images are made of discrete picture
elements arranged in a matrix The size of the image is described in the binary number system
Modern imaging systems are at least 1024 x 1024
4096 x 4096 is being developed for digital radiography
Matrix = each cell corresponds to a specific location on the image
Pixel
Pixels
Digital Images ndash Bit Depth
bull Pixel values can be any bit depth (values from 0 to 1023)
bull Bit depth = or gray shades available for image display
bull Image contrast can be manipulated to stretched or contracted to alter the displayed contrast
bull Typically use ldquowindow widthrdquo and ldquowindow levelrdquo to alter displayed contrast and brightness
Digital - Grayscale
Bit depth Number of gray shades
available for display 8 bit 256 10 bit 1024 12 bit 4096 4 bit 16384
Display Bit Depth1 bit 6 bit 8 bit
2 shades 64 shades 256 shades
Computed Radiography As the plate is scanned ldquoreadrdquo data is collected
at a specific frequency = Sampling frequency
Spatial resolution determined by sampling frequency
With some systems the smaller IRrsquos have higher sampling frequencies amp more pixels per mm = more spatial resolution
Signal Loss (reducing image quality) Signal-to-Noise Ratio
Principle source of noise on the image is scatter radiation
Scattering of emitted light off screen
The efficiency of the photomultiplier tubes (PMTs) and photodiodes (PDs)
Improving Signal-to-Noise Ratio
Optical filter is used to prevent the longer-wavelength laser light affecting the image formation
Increasing exposure to IR Newer CR systems are better at reducing noise at lower exposure levels
Technique Selections
What are some factors that technologist must take into consideration when selecting a technique
What regulates that technologists to select appropriate techniques in FS CR amp DR
Screen Film
Self regulating system The receptor speed and film HampD curve defined
the proper exposure Achieving optimal OD guaranteed appropriate
exposure to the patient Over exposed = dark image Correct exposure = correct OD Under exposed = light image
Characteristic curveof radiographic film
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 24: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/24.jpg)
Imaging Plate (IP)
Contained in a cassette
Handled the same as SF cassettes
Processed more like daylight processor with no chemicals
IP has lead backing to reduce scatter
Imaging Plate Construction
A thin sheet of plastic
IPrsquos have several layersA protective layer This is a very thin tough
clear plastic that protects the phosphor layer A phosphor or active layer This is a layer of
photostimulable phosphor that ldquotrapsrdquo electrons during exposure
Active Layer - Crystals The materials that make up the PSP plate
are from the barium fluorohalide family
Barium fluorohalide chlorohalide or bromohalide crystals The most common crystal uses is barium fluorohalide with europium
Acquiring the Image
The remnant beam interacts with electrons in the barium fluorohalide crystals
This interaction stimulates or gives energy to electrons in the crystals allowing them to enter the conductive layer
The Conductuve layer is where they are
trapped in an area of the crystal known as the color or phosphor center
Acquiring the Image cont
This trapped signal will remain for hours even days although deterioration begins almost immediately IR should be processed as soon as possible
The trapped signal is never completely lost
Imaging Plate Construction
A reflective layer This is a layer that sends light in a forward direction when released in the cassette reader This layer may be black to reduce the spread of stimulating light and the escape of emitted light Some detail is lost in this process
Imaging Plate Construction Conductive layer This is a layer of material that
absorbs and reduces static electricity A color layer Newer plates may contain a color
layer located between the active layer and the support that absorbs the stimulating light but reflects emitted light
A support layer This is a semirigid material that gives the imaging sheet some strength
A backing layer This is a soft polymer that protects the back of the cassette
Cross section of a PSP screen
Needle PSP increase the absorption of x-rays and limit the spread of light emission
IP Design
Designed to optimize the intensity of light release (CE)
Enhance the absorption of x-rays (DQE)
Limit the spread of light emission for more detail
Photostimulable Luminescence When the cassette is put into the reader the
imaging plate is extracted and scanned With a helium laser beam or in more recent
systems solid-state laser diodes This beam about 100μm wide with a wavelength
of 633 nm (or 670 to 690 nm for solid state) Scans the plate with red light in a raster pattern
and gives energy to the trapped electrons
X-ray interaction with a PSP screen
1
2
X-ray interactions with the screen phosphors causes an e- to excited
When e- return to groundstate visible light is emitted
CR Phosphor PlatesCR Phosphor Plates
ABSORPTION EMISSION
X-RAY
LIGHT
LASER STIMULATION
ELECTRONTRAP
ELECTRONTRAP
CR Reader ndash PSP plate
Stimulates the matrix of trapped E- by a RED OR ULTRAVIOLET laser light
Trapped E- energy is released in a form of VIOLETBLUE light
Violet light is captured by PMT ndash is amplified and converted into a digital signal
Sequence of CR imaging
PMT
Beam deflector
LaserSource
Light channeling guide
Plate translation Sub-scan direction
Laser beam Scan direction
Output Signal
Reference detec tor
Beam splitter
Cylindrical m irrorf-thetalens
Amplifier
ADC
To imageprocessor
How CR works
Released light is captured by a PMT (photo
multiplier tube) An ultrasensitive photomultiplier tube or CCD (charged couple device)
PSP light is amplified by the PMT or CCD
This light is sent to the analog to digital converter (ADC) To convert light to binary
PMT (photomultiplier tube) The intensity (brightness) of the light ndash
correlates to the density on the image
So lots of light will correlate to what size number amp what color on the image
The digital numeric values are stored in matrix form called pixels for display on a cathode ray tube (CRT) or printed on film
ERASING THE SCREEN ~50 of trapped electrons released during ldquoreadrdquo After image is recorded Plate is erased with high intensity white light and
re-used Erasing should be done after every exposure or
at minimum every 24 hours to avoid ghosting on future images
Basics of Digital Images
bull digital images are a (matrix) of pixel (picture element) values
Pixels Digital images are made of discrete picture
elements arranged in a matrix The size of the image is described in the binary number system
Modern imaging systems are at least 1024 x 1024
4096 x 4096 is being developed for digital radiography
Matrix = each cell corresponds to a specific location on the image
Pixel
Pixels
Digital Images ndash Bit Depth
bull Pixel values can be any bit depth (values from 0 to 1023)
bull Bit depth = or gray shades available for image display
bull Image contrast can be manipulated to stretched or contracted to alter the displayed contrast
bull Typically use ldquowindow widthrdquo and ldquowindow levelrdquo to alter displayed contrast and brightness
Digital - Grayscale
Bit depth Number of gray shades
available for display 8 bit 256 10 bit 1024 12 bit 4096 4 bit 16384
Display Bit Depth1 bit 6 bit 8 bit
2 shades 64 shades 256 shades
Computed Radiography As the plate is scanned ldquoreadrdquo data is collected
at a specific frequency = Sampling frequency
Spatial resolution determined by sampling frequency
With some systems the smaller IRrsquos have higher sampling frequencies amp more pixels per mm = more spatial resolution
Signal Loss (reducing image quality) Signal-to-Noise Ratio
Principle source of noise on the image is scatter radiation
Scattering of emitted light off screen
The efficiency of the photomultiplier tubes (PMTs) and photodiodes (PDs)
Improving Signal-to-Noise Ratio
Optical filter is used to prevent the longer-wavelength laser light affecting the image formation
Increasing exposure to IR Newer CR systems are better at reducing noise at lower exposure levels
Technique Selections
What are some factors that technologist must take into consideration when selecting a technique
What regulates that technologists to select appropriate techniques in FS CR amp DR
Screen Film
Self regulating system The receptor speed and film HampD curve defined
the proper exposure Achieving optimal OD guaranteed appropriate
exposure to the patient Over exposed = dark image Correct exposure = correct OD Under exposed = light image
Characteristic curveof radiographic film
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 25: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/25.jpg)
Imaging Plate Construction
A thin sheet of plastic
IPrsquos have several layersA protective layer This is a very thin tough
clear plastic that protects the phosphor layer A phosphor or active layer This is a layer of
photostimulable phosphor that ldquotrapsrdquo electrons during exposure
Active Layer - Crystals The materials that make up the PSP plate
are from the barium fluorohalide family
Barium fluorohalide chlorohalide or bromohalide crystals The most common crystal uses is barium fluorohalide with europium
Acquiring the Image
The remnant beam interacts with electrons in the barium fluorohalide crystals
This interaction stimulates or gives energy to electrons in the crystals allowing them to enter the conductive layer
The Conductuve layer is where they are
trapped in an area of the crystal known as the color or phosphor center
Acquiring the Image cont
This trapped signal will remain for hours even days although deterioration begins almost immediately IR should be processed as soon as possible
The trapped signal is never completely lost
Imaging Plate Construction
A reflective layer This is a layer that sends light in a forward direction when released in the cassette reader This layer may be black to reduce the spread of stimulating light and the escape of emitted light Some detail is lost in this process
Imaging Plate Construction Conductive layer This is a layer of material that
absorbs and reduces static electricity A color layer Newer plates may contain a color
layer located between the active layer and the support that absorbs the stimulating light but reflects emitted light
A support layer This is a semirigid material that gives the imaging sheet some strength
A backing layer This is a soft polymer that protects the back of the cassette
Cross section of a PSP screen
Needle PSP increase the absorption of x-rays and limit the spread of light emission
IP Design
Designed to optimize the intensity of light release (CE)
Enhance the absorption of x-rays (DQE)
Limit the spread of light emission for more detail
Photostimulable Luminescence When the cassette is put into the reader the
imaging plate is extracted and scanned With a helium laser beam or in more recent
systems solid-state laser diodes This beam about 100μm wide with a wavelength
of 633 nm (or 670 to 690 nm for solid state) Scans the plate with red light in a raster pattern
and gives energy to the trapped electrons
X-ray interaction with a PSP screen
1
2
X-ray interactions with the screen phosphors causes an e- to excited
When e- return to groundstate visible light is emitted
CR Phosphor PlatesCR Phosphor Plates
ABSORPTION EMISSION
X-RAY
LIGHT
LASER STIMULATION
ELECTRONTRAP
ELECTRONTRAP
CR Reader ndash PSP plate
Stimulates the matrix of trapped E- by a RED OR ULTRAVIOLET laser light
Trapped E- energy is released in a form of VIOLETBLUE light
Violet light is captured by PMT ndash is amplified and converted into a digital signal
Sequence of CR imaging
PMT
Beam deflector
LaserSource
Light channeling guide
Plate translation Sub-scan direction
Laser beam Scan direction
Output Signal
Reference detec tor
Beam splitter
Cylindrical m irrorf-thetalens
Amplifier
ADC
To imageprocessor
How CR works
Released light is captured by a PMT (photo
multiplier tube) An ultrasensitive photomultiplier tube or CCD (charged couple device)
PSP light is amplified by the PMT or CCD
This light is sent to the analog to digital converter (ADC) To convert light to binary
PMT (photomultiplier tube) The intensity (brightness) of the light ndash
correlates to the density on the image
So lots of light will correlate to what size number amp what color on the image
The digital numeric values are stored in matrix form called pixels for display on a cathode ray tube (CRT) or printed on film
ERASING THE SCREEN ~50 of trapped electrons released during ldquoreadrdquo After image is recorded Plate is erased with high intensity white light and
re-used Erasing should be done after every exposure or
at minimum every 24 hours to avoid ghosting on future images
Basics of Digital Images
bull digital images are a (matrix) of pixel (picture element) values
Pixels Digital images are made of discrete picture
elements arranged in a matrix The size of the image is described in the binary number system
Modern imaging systems are at least 1024 x 1024
4096 x 4096 is being developed for digital radiography
Matrix = each cell corresponds to a specific location on the image
Pixel
Pixels
Digital Images ndash Bit Depth
bull Pixel values can be any bit depth (values from 0 to 1023)
bull Bit depth = or gray shades available for image display
bull Image contrast can be manipulated to stretched or contracted to alter the displayed contrast
bull Typically use ldquowindow widthrdquo and ldquowindow levelrdquo to alter displayed contrast and brightness
Digital - Grayscale
Bit depth Number of gray shades
available for display 8 bit 256 10 bit 1024 12 bit 4096 4 bit 16384
Display Bit Depth1 bit 6 bit 8 bit
2 shades 64 shades 256 shades
Computed Radiography As the plate is scanned ldquoreadrdquo data is collected
at a specific frequency = Sampling frequency
Spatial resolution determined by sampling frequency
With some systems the smaller IRrsquos have higher sampling frequencies amp more pixels per mm = more spatial resolution
Signal Loss (reducing image quality) Signal-to-Noise Ratio
Principle source of noise on the image is scatter radiation
Scattering of emitted light off screen
The efficiency of the photomultiplier tubes (PMTs) and photodiodes (PDs)
Improving Signal-to-Noise Ratio
Optical filter is used to prevent the longer-wavelength laser light affecting the image formation
Increasing exposure to IR Newer CR systems are better at reducing noise at lower exposure levels
Technique Selections
What are some factors that technologist must take into consideration when selecting a technique
What regulates that technologists to select appropriate techniques in FS CR amp DR
Screen Film
Self regulating system The receptor speed and film HampD curve defined
the proper exposure Achieving optimal OD guaranteed appropriate
exposure to the patient Over exposed = dark image Correct exposure = correct OD Under exposed = light image
Characteristic curveof radiographic film
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 26: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/26.jpg)
Active Layer - Crystals The materials that make up the PSP plate
are from the barium fluorohalide family
Barium fluorohalide chlorohalide or bromohalide crystals The most common crystal uses is barium fluorohalide with europium
Acquiring the Image
The remnant beam interacts with electrons in the barium fluorohalide crystals
This interaction stimulates or gives energy to electrons in the crystals allowing them to enter the conductive layer
The Conductuve layer is where they are
trapped in an area of the crystal known as the color or phosphor center
Acquiring the Image cont
This trapped signal will remain for hours even days although deterioration begins almost immediately IR should be processed as soon as possible
The trapped signal is never completely lost
Imaging Plate Construction
A reflective layer This is a layer that sends light in a forward direction when released in the cassette reader This layer may be black to reduce the spread of stimulating light and the escape of emitted light Some detail is lost in this process
Imaging Plate Construction Conductive layer This is a layer of material that
absorbs and reduces static electricity A color layer Newer plates may contain a color
layer located between the active layer and the support that absorbs the stimulating light but reflects emitted light
A support layer This is a semirigid material that gives the imaging sheet some strength
A backing layer This is a soft polymer that protects the back of the cassette
Cross section of a PSP screen
Needle PSP increase the absorption of x-rays and limit the spread of light emission
IP Design
Designed to optimize the intensity of light release (CE)
Enhance the absorption of x-rays (DQE)
Limit the spread of light emission for more detail
Photostimulable Luminescence When the cassette is put into the reader the
imaging plate is extracted and scanned With a helium laser beam or in more recent
systems solid-state laser diodes This beam about 100μm wide with a wavelength
of 633 nm (or 670 to 690 nm for solid state) Scans the plate with red light in a raster pattern
and gives energy to the trapped electrons
X-ray interaction with a PSP screen
1
2
X-ray interactions with the screen phosphors causes an e- to excited
When e- return to groundstate visible light is emitted
CR Phosphor PlatesCR Phosphor Plates
ABSORPTION EMISSION
X-RAY
LIGHT
LASER STIMULATION
ELECTRONTRAP
ELECTRONTRAP
CR Reader ndash PSP plate
Stimulates the matrix of trapped E- by a RED OR ULTRAVIOLET laser light
Trapped E- energy is released in a form of VIOLETBLUE light
Violet light is captured by PMT ndash is amplified and converted into a digital signal
Sequence of CR imaging
PMT
Beam deflector
LaserSource
Light channeling guide
Plate translation Sub-scan direction
Laser beam Scan direction
Output Signal
Reference detec tor
Beam splitter
Cylindrical m irrorf-thetalens
Amplifier
ADC
To imageprocessor
How CR works
Released light is captured by a PMT (photo
multiplier tube) An ultrasensitive photomultiplier tube or CCD (charged couple device)
PSP light is amplified by the PMT or CCD
This light is sent to the analog to digital converter (ADC) To convert light to binary
PMT (photomultiplier tube) The intensity (brightness) of the light ndash
correlates to the density on the image
So lots of light will correlate to what size number amp what color on the image
The digital numeric values are stored in matrix form called pixels for display on a cathode ray tube (CRT) or printed on film
ERASING THE SCREEN ~50 of trapped electrons released during ldquoreadrdquo After image is recorded Plate is erased with high intensity white light and
re-used Erasing should be done after every exposure or
at minimum every 24 hours to avoid ghosting on future images
Basics of Digital Images
bull digital images are a (matrix) of pixel (picture element) values
Pixels Digital images are made of discrete picture
elements arranged in a matrix The size of the image is described in the binary number system
Modern imaging systems are at least 1024 x 1024
4096 x 4096 is being developed for digital radiography
Matrix = each cell corresponds to a specific location on the image
Pixel
Pixels
Digital Images ndash Bit Depth
bull Pixel values can be any bit depth (values from 0 to 1023)
bull Bit depth = or gray shades available for image display
bull Image contrast can be manipulated to stretched or contracted to alter the displayed contrast
bull Typically use ldquowindow widthrdquo and ldquowindow levelrdquo to alter displayed contrast and brightness
Digital - Grayscale
Bit depth Number of gray shades
available for display 8 bit 256 10 bit 1024 12 bit 4096 4 bit 16384
Display Bit Depth1 bit 6 bit 8 bit
2 shades 64 shades 256 shades
Computed Radiography As the plate is scanned ldquoreadrdquo data is collected
at a specific frequency = Sampling frequency
Spatial resolution determined by sampling frequency
With some systems the smaller IRrsquos have higher sampling frequencies amp more pixels per mm = more spatial resolution
Signal Loss (reducing image quality) Signal-to-Noise Ratio
Principle source of noise on the image is scatter radiation
Scattering of emitted light off screen
The efficiency of the photomultiplier tubes (PMTs) and photodiodes (PDs)
Improving Signal-to-Noise Ratio
Optical filter is used to prevent the longer-wavelength laser light affecting the image formation
Increasing exposure to IR Newer CR systems are better at reducing noise at lower exposure levels
Technique Selections
What are some factors that technologist must take into consideration when selecting a technique
What regulates that technologists to select appropriate techniques in FS CR amp DR
Screen Film
Self regulating system The receptor speed and film HampD curve defined
the proper exposure Achieving optimal OD guaranteed appropriate
exposure to the patient Over exposed = dark image Correct exposure = correct OD Under exposed = light image
Characteristic curveof radiographic film
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 27: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/27.jpg)
Acquiring the Image
The remnant beam interacts with electrons in the barium fluorohalide crystals
This interaction stimulates or gives energy to electrons in the crystals allowing them to enter the conductive layer
The Conductuve layer is where they are
trapped in an area of the crystal known as the color or phosphor center
Acquiring the Image cont
This trapped signal will remain for hours even days although deterioration begins almost immediately IR should be processed as soon as possible
The trapped signal is never completely lost
Imaging Plate Construction
A reflective layer This is a layer that sends light in a forward direction when released in the cassette reader This layer may be black to reduce the spread of stimulating light and the escape of emitted light Some detail is lost in this process
Imaging Plate Construction Conductive layer This is a layer of material that
absorbs and reduces static electricity A color layer Newer plates may contain a color
layer located between the active layer and the support that absorbs the stimulating light but reflects emitted light
A support layer This is a semirigid material that gives the imaging sheet some strength
A backing layer This is a soft polymer that protects the back of the cassette
Cross section of a PSP screen
Needle PSP increase the absorption of x-rays and limit the spread of light emission
IP Design
Designed to optimize the intensity of light release (CE)
Enhance the absorption of x-rays (DQE)
Limit the spread of light emission for more detail
Photostimulable Luminescence When the cassette is put into the reader the
imaging plate is extracted and scanned With a helium laser beam or in more recent
systems solid-state laser diodes This beam about 100μm wide with a wavelength
of 633 nm (or 670 to 690 nm for solid state) Scans the plate with red light in a raster pattern
and gives energy to the trapped electrons
X-ray interaction with a PSP screen
1
2
X-ray interactions with the screen phosphors causes an e- to excited
When e- return to groundstate visible light is emitted
CR Phosphor PlatesCR Phosphor Plates
ABSORPTION EMISSION
X-RAY
LIGHT
LASER STIMULATION
ELECTRONTRAP
ELECTRONTRAP
CR Reader ndash PSP plate
Stimulates the matrix of trapped E- by a RED OR ULTRAVIOLET laser light
Trapped E- energy is released in a form of VIOLETBLUE light
Violet light is captured by PMT ndash is amplified and converted into a digital signal
Sequence of CR imaging
PMT
Beam deflector
LaserSource
Light channeling guide
Plate translation Sub-scan direction
Laser beam Scan direction
Output Signal
Reference detec tor
Beam splitter
Cylindrical m irrorf-thetalens
Amplifier
ADC
To imageprocessor
How CR works
Released light is captured by a PMT (photo
multiplier tube) An ultrasensitive photomultiplier tube or CCD (charged couple device)
PSP light is amplified by the PMT or CCD
This light is sent to the analog to digital converter (ADC) To convert light to binary
PMT (photomultiplier tube) The intensity (brightness) of the light ndash
correlates to the density on the image
So lots of light will correlate to what size number amp what color on the image
The digital numeric values are stored in matrix form called pixels for display on a cathode ray tube (CRT) or printed on film
ERASING THE SCREEN ~50 of trapped electrons released during ldquoreadrdquo After image is recorded Plate is erased with high intensity white light and
re-used Erasing should be done after every exposure or
at minimum every 24 hours to avoid ghosting on future images
Basics of Digital Images
bull digital images are a (matrix) of pixel (picture element) values
Pixels Digital images are made of discrete picture
elements arranged in a matrix The size of the image is described in the binary number system
Modern imaging systems are at least 1024 x 1024
4096 x 4096 is being developed for digital radiography
Matrix = each cell corresponds to a specific location on the image
Pixel
Pixels
Digital Images ndash Bit Depth
bull Pixel values can be any bit depth (values from 0 to 1023)
bull Bit depth = or gray shades available for image display
bull Image contrast can be manipulated to stretched or contracted to alter the displayed contrast
bull Typically use ldquowindow widthrdquo and ldquowindow levelrdquo to alter displayed contrast and brightness
Digital - Grayscale
Bit depth Number of gray shades
available for display 8 bit 256 10 bit 1024 12 bit 4096 4 bit 16384
Display Bit Depth1 bit 6 bit 8 bit
2 shades 64 shades 256 shades
Computed Radiography As the plate is scanned ldquoreadrdquo data is collected
at a specific frequency = Sampling frequency
Spatial resolution determined by sampling frequency
With some systems the smaller IRrsquos have higher sampling frequencies amp more pixels per mm = more spatial resolution
Signal Loss (reducing image quality) Signal-to-Noise Ratio
Principle source of noise on the image is scatter radiation
Scattering of emitted light off screen
The efficiency of the photomultiplier tubes (PMTs) and photodiodes (PDs)
Improving Signal-to-Noise Ratio
Optical filter is used to prevent the longer-wavelength laser light affecting the image formation
Increasing exposure to IR Newer CR systems are better at reducing noise at lower exposure levels
Technique Selections
What are some factors that technologist must take into consideration when selecting a technique
What regulates that technologists to select appropriate techniques in FS CR amp DR
Screen Film
Self regulating system The receptor speed and film HampD curve defined
the proper exposure Achieving optimal OD guaranteed appropriate
exposure to the patient Over exposed = dark image Correct exposure = correct OD Under exposed = light image
Characteristic curveof radiographic film
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 28: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/28.jpg)
Acquiring the Image cont
This trapped signal will remain for hours even days although deterioration begins almost immediately IR should be processed as soon as possible
The trapped signal is never completely lost
Imaging Plate Construction
A reflective layer This is a layer that sends light in a forward direction when released in the cassette reader This layer may be black to reduce the spread of stimulating light and the escape of emitted light Some detail is lost in this process
Imaging Plate Construction Conductive layer This is a layer of material that
absorbs and reduces static electricity A color layer Newer plates may contain a color
layer located between the active layer and the support that absorbs the stimulating light but reflects emitted light
A support layer This is a semirigid material that gives the imaging sheet some strength
A backing layer This is a soft polymer that protects the back of the cassette
Cross section of a PSP screen
Needle PSP increase the absorption of x-rays and limit the spread of light emission
IP Design
Designed to optimize the intensity of light release (CE)
Enhance the absorption of x-rays (DQE)
Limit the spread of light emission for more detail
Photostimulable Luminescence When the cassette is put into the reader the
imaging plate is extracted and scanned With a helium laser beam or in more recent
systems solid-state laser diodes This beam about 100μm wide with a wavelength
of 633 nm (or 670 to 690 nm for solid state) Scans the plate with red light in a raster pattern
and gives energy to the trapped electrons
X-ray interaction with a PSP screen
1
2
X-ray interactions with the screen phosphors causes an e- to excited
When e- return to groundstate visible light is emitted
CR Phosphor PlatesCR Phosphor Plates
ABSORPTION EMISSION
X-RAY
LIGHT
LASER STIMULATION
ELECTRONTRAP
ELECTRONTRAP
CR Reader ndash PSP plate
Stimulates the matrix of trapped E- by a RED OR ULTRAVIOLET laser light
Trapped E- energy is released in a form of VIOLETBLUE light
Violet light is captured by PMT ndash is amplified and converted into a digital signal
Sequence of CR imaging
PMT
Beam deflector
LaserSource
Light channeling guide
Plate translation Sub-scan direction
Laser beam Scan direction
Output Signal
Reference detec tor
Beam splitter
Cylindrical m irrorf-thetalens
Amplifier
ADC
To imageprocessor
How CR works
Released light is captured by a PMT (photo
multiplier tube) An ultrasensitive photomultiplier tube or CCD (charged couple device)
PSP light is amplified by the PMT or CCD
This light is sent to the analog to digital converter (ADC) To convert light to binary
PMT (photomultiplier tube) The intensity (brightness) of the light ndash
correlates to the density on the image
So lots of light will correlate to what size number amp what color on the image
The digital numeric values are stored in matrix form called pixels for display on a cathode ray tube (CRT) or printed on film
ERASING THE SCREEN ~50 of trapped electrons released during ldquoreadrdquo After image is recorded Plate is erased with high intensity white light and
re-used Erasing should be done after every exposure or
at minimum every 24 hours to avoid ghosting on future images
Basics of Digital Images
bull digital images are a (matrix) of pixel (picture element) values
Pixels Digital images are made of discrete picture
elements arranged in a matrix The size of the image is described in the binary number system
Modern imaging systems are at least 1024 x 1024
4096 x 4096 is being developed for digital radiography
Matrix = each cell corresponds to a specific location on the image
Pixel
Pixels
Digital Images ndash Bit Depth
bull Pixel values can be any bit depth (values from 0 to 1023)
bull Bit depth = or gray shades available for image display
bull Image contrast can be manipulated to stretched or contracted to alter the displayed contrast
bull Typically use ldquowindow widthrdquo and ldquowindow levelrdquo to alter displayed contrast and brightness
Digital - Grayscale
Bit depth Number of gray shades
available for display 8 bit 256 10 bit 1024 12 bit 4096 4 bit 16384
Display Bit Depth1 bit 6 bit 8 bit
2 shades 64 shades 256 shades
Computed Radiography As the plate is scanned ldquoreadrdquo data is collected
at a specific frequency = Sampling frequency
Spatial resolution determined by sampling frequency
With some systems the smaller IRrsquos have higher sampling frequencies amp more pixels per mm = more spatial resolution
Signal Loss (reducing image quality) Signal-to-Noise Ratio
Principle source of noise on the image is scatter radiation
Scattering of emitted light off screen
The efficiency of the photomultiplier tubes (PMTs) and photodiodes (PDs)
Improving Signal-to-Noise Ratio
Optical filter is used to prevent the longer-wavelength laser light affecting the image formation
Increasing exposure to IR Newer CR systems are better at reducing noise at lower exposure levels
Technique Selections
What are some factors that technologist must take into consideration when selecting a technique
What regulates that technologists to select appropriate techniques in FS CR amp DR
Screen Film
Self regulating system The receptor speed and film HampD curve defined
the proper exposure Achieving optimal OD guaranteed appropriate
exposure to the patient Over exposed = dark image Correct exposure = correct OD Under exposed = light image
Characteristic curveof radiographic film
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 29: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/29.jpg)
Imaging Plate Construction
A reflective layer This is a layer that sends light in a forward direction when released in the cassette reader This layer may be black to reduce the spread of stimulating light and the escape of emitted light Some detail is lost in this process
Imaging Plate Construction Conductive layer This is a layer of material that
absorbs and reduces static electricity A color layer Newer plates may contain a color
layer located between the active layer and the support that absorbs the stimulating light but reflects emitted light
A support layer This is a semirigid material that gives the imaging sheet some strength
A backing layer This is a soft polymer that protects the back of the cassette
Cross section of a PSP screen
Needle PSP increase the absorption of x-rays and limit the spread of light emission
IP Design
Designed to optimize the intensity of light release (CE)
Enhance the absorption of x-rays (DQE)
Limit the spread of light emission for more detail
Photostimulable Luminescence When the cassette is put into the reader the
imaging plate is extracted and scanned With a helium laser beam or in more recent
systems solid-state laser diodes This beam about 100μm wide with a wavelength
of 633 nm (or 670 to 690 nm for solid state) Scans the plate with red light in a raster pattern
and gives energy to the trapped electrons
X-ray interaction with a PSP screen
1
2
X-ray interactions with the screen phosphors causes an e- to excited
When e- return to groundstate visible light is emitted
CR Phosphor PlatesCR Phosphor Plates
ABSORPTION EMISSION
X-RAY
LIGHT
LASER STIMULATION
ELECTRONTRAP
ELECTRONTRAP
CR Reader ndash PSP plate
Stimulates the matrix of trapped E- by a RED OR ULTRAVIOLET laser light
Trapped E- energy is released in a form of VIOLETBLUE light
Violet light is captured by PMT ndash is amplified and converted into a digital signal
Sequence of CR imaging
PMT
Beam deflector
LaserSource
Light channeling guide
Plate translation Sub-scan direction
Laser beam Scan direction
Output Signal
Reference detec tor
Beam splitter
Cylindrical m irrorf-thetalens
Amplifier
ADC
To imageprocessor
How CR works
Released light is captured by a PMT (photo
multiplier tube) An ultrasensitive photomultiplier tube or CCD (charged couple device)
PSP light is amplified by the PMT or CCD
This light is sent to the analog to digital converter (ADC) To convert light to binary
PMT (photomultiplier tube) The intensity (brightness) of the light ndash
correlates to the density on the image
So lots of light will correlate to what size number amp what color on the image
The digital numeric values are stored in matrix form called pixels for display on a cathode ray tube (CRT) or printed on film
ERASING THE SCREEN ~50 of trapped electrons released during ldquoreadrdquo After image is recorded Plate is erased with high intensity white light and
re-used Erasing should be done after every exposure or
at minimum every 24 hours to avoid ghosting on future images
Basics of Digital Images
bull digital images are a (matrix) of pixel (picture element) values
Pixels Digital images are made of discrete picture
elements arranged in a matrix The size of the image is described in the binary number system
Modern imaging systems are at least 1024 x 1024
4096 x 4096 is being developed for digital radiography
Matrix = each cell corresponds to a specific location on the image
Pixel
Pixels
Digital Images ndash Bit Depth
bull Pixel values can be any bit depth (values from 0 to 1023)
bull Bit depth = or gray shades available for image display
bull Image contrast can be manipulated to stretched or contracted to alter the displayed contrast
bull Typically use ldquowindow widthrdquo and ldquowindow levelrdquo to alter displayed contrast and brightness
Digital - Grayscale
Bit depth Number of gray shades
available for display 8 bit 256 10 bit 1024 12 bit 4096 4 bit 16384
Display Bit Depth1 bit 6 bit 8 bit
2 shades 64 shades 256 shades
Computed Radiography As the plate is scanned ldquoreadrdquo data is collected
at a specific frequency = Sampling frequency
Spatial resolution determined by sampling frequency
With some systems the smaller IRrsquos have higher sampling frequencies amp more pixels per mm = more spatial resolution
Signal Loss (reducing image quality) Signal-to-Noise Ratio
Principle source of noise on the image is scatter radiation
Scattering of emitted light off screen
The efficiency of the photomultiplier tubes (PMTs) and photodiodes (PDs)
Improving Signal-to-Noise Ratio
Optical filter is used to prevent the longer-wavelength laser light affecting the image formation
Increasing exposure to IR Newer CR systems are better at reducing noise at lower exposure levels
Technique Selections
What are some factors that technologist must take into consideration when selecting a technique
What regulates that technologists to select appropriate techniques in FS CR amp DR
Screen Film
Self regulating system The receptor speed and film HampD curve defined
the proper exposure Achieving optimal OD guaranteed appropriate
exposure to the patient Over exposed = dark image Correct exposure = correct OD Under exposed = light image
Characteristic curveof radiographic film
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 30: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/30.jpg)
Imaging Plate Construction Conductive layer This is a layer of material that
absorbs and reduces static electricity A color layer Newer plates may contain a color
layer located between the active layer and the support that absorbs the stimulating light but reflects emitted light
A support layer This is a semirigid material that gives the imaging sheet some strength
A backing layer This is a soft polymer that protects the back of the cassette
Cross section of a PSP screen
Needle PSP increase the absorption of x-rays and limit the spread of light emission
IP Design
Designed to optimize the intensity of light release (CE)
Enhance the absorption of x-rays (DQE)
Limit the spread of light emission for more detail
Photostimulable Luminescence When the cassette is put into the reader the
imaging plate is extracted and scanned With a helium laser beam or in more recent
systems solid-state laser diodes This beam about 100μm wide with a wavelength
of 633 nm (or 670 to 690 nm for solid state) Scans the plate with red light in a raster pattern
and gives energy to the trapped electrons
X-ray interaction with a PSP screen
1
2
X-ray interactions with the screen phosphors causes an e- to excited
When e- return to groundstate visible light is emitted
CR Phosphor PlatesCR Phosphor Plates
ABSORPTION EMISSION
X-RAY
LIGHT
LASER STIMULATION
ELECTRONTRAP
ELECTRONTRAP
CR Reader ndash PSP plate
Stimulates the matrix of trapped E- by a RED OR ULTRAVIOLET laser light
Trapped E- energy is released in a form of VIOLETBLUE light
Violet light is captured by PMT ndash is amplified and converted into a digital signal
Sequence of CR imaging
PMT
Beam deflector
LaserSource
Light channeling guide
Plate translation Sub-scan direction
Laser beam Scan direction
Output Signal
Reference detec tor
Beam splitter
Cylindrical m irrorf-thetalens
Amplifier
ADC
To imageprocessor
How CR works
Released light is captured by a PMT (photo
multiplier tube) An ultrasensitive photomultiplier tube or CCD (charged couple device)
PSP light is amplified by the PMT or CCD
This light is sent to the analog to digital converter (ADC) To convert light to binary
PMT (photomultiplier tube) The intensity (brightness) of the light ndash
correlates to the density on the image
So lots of light will correlate to what size number amp what color on the image
The digital numeric values are stored in matrix form called pixels for display on a cathode ray tube (CRT) or printed on film
ERASING THE SCREEN ~50 of trapped electrons released during ldquoreadrdquo After image is recorded Plate is erased with high intensity white light and
re-used Erasing should be done after every exposure or
at minimum every 24 hours to avoid ghosting on future images
Basics of Digital Images
bull digital images are a (matrix) of pixel (picture element) values
Pixels Digital images are made of discrete picture
elements arranged in a matrix The size of the image is described in the binary number system
Modern imaging systems are at least 1024 x 1024
4096 x 4096 is being developed for digital radiography
Matrix = each cell corresponds to a specific location on the image
Pixel
Pixels
Digital Images ndash Bit Depth
bull Pixel values can be any bit depth (values from 0 to 1023)
bull Bit depth = or gray shades available for image display
bull Image contrast can be manipulated to stretched or contracted to alter the displayed contrast
bull Typically use ldquowindow widthrdquo and ldquowindow levelrdquo to alter displayed contrast and brightness
Digital - Grayscale
Bit depth Number of gray shades
available for display 8 bit 256 10 bit 1024 12 bit 4096 4 bit 16384
Display Bit Depth1 bit 6 bit 8 bit
2 shades 64 shades 256 shades
Computed Radiography As the plate is scanned ldquoreadrdquo data is collected
at a specific frequency = Sampling frequency
Spatial resolution determined by sampling frequency
With some systems the smaller IRrsquos have higher sampling frequencies amp more pixels per mm = more spatial resolution
Signal Loss (reducing image quality) Signal-to-Noise Ratio
Principle source of noise on the image is scatter radiation
Scattering of emitted light off screen
The efficiency of the photomultiplier tubes (PMTs) and photodiodes (PDs)
Improving Signal-to-Noise Ratio
Optical filter is used to prevent the longer-wavelength laser light affecting the image formation
Increasing exposure to IR Newer CR systems are better at reducing noise at lower exposure levels
Technique Selections
What are some factors that technologist must take into consideration when selecting a technique
What regulates that technologists to select appropriate techniques in FS CR amp DR
Screen Film
Self regulating system The receptor speed and film HampD curve defined
the proper exposure Achieving optimal OD guaranteed appropriate
exposure to the patient Over exposed = dark image Correct exposure = correct OD Under exposed = light image
Characteristic curveof radiographic film
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 31: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/31.jpg)
Cross section of a PSP screen
Needle PSP increase the absorption of x-rays and limit the spread of light emission
IP Design
Designed to optimize the intensity of light release (CE)
Enhance the absorption of x-rays (DQE)
Limit the spread of light emission for more detail
Photostimulable Luminescence When the cassette is put into the reader the
imaging plate is extracted and scanned With a helium laser beam or in more recent
systems solid-state laser diodes This beam about 100μm wide with a wavelength
of 633 nm (or 670 to 690 nm for solid state) Scans the plate with red light in a raster pattern
and gives energy to the trapped electrons
X-ray interaction with a PSP screen
1
2
X-ray interactions with the screen phosphors causes an e- to excited
When e- return to groundstate visible light is emitted
CR Phosphor PlatesCR Phosphor Plates
ABSORPTION EMISSION
X-RAY
LIGHT
LASER STIMULATION
ELECTRONTRAP
ELECTRONTRAP
CR Reader ndash PSP plate
Stimulates the matrix of trapped E- by a RED OR ULTRAVIOLET laser light
Trapped E- energy is released in a form of VIOLETBLUE light
Violet light is captured by PMT ndash is amplified and converted into a digital signal
Sequence of CR imaging
PMT
Beam deflector
LaserSource
Light channeling guide
Plate translation Sub-scan direction
Laser beam Scan direction
Output Signal
Reference detec tor
Beam splitter
Cylindrical m irrorf-thetalens
Amplifier
ADC
To imageprocessor
How CR works
Released light is captured by a PMT (photo
multiplier tube) An ultrasensitive photomultiplier tube or CCD (charged couple device)
PSP light is amplified by the PMT or CCD
This light is sent to the analog to digital converter (ADC) To convert light to binary
PMT (photomultiplier tube) The intensity (brightness) of the light ndash
correlates to the density on the image
So lots of light will correlate to what size number amp what color on the image
The digital numeric values are stored in matrix form called pixels for display on a cathode ray tube (CRT) or printed on film
ERASING THE SCREEN ~50 of trapped electrons released during ldquoreadrdquo After image is recorded Plate is erased with high intensity white light and
re-used Erasing should be done after every exposure or
at minimum every 24 hours to avoid ghosting on future images
Basics of Digital Images
bull digital images are a (matrix) of pixel (picture element) values
Pixels Digital images are made of discrete picture
elements arranged in a matrix The size of the image is described in the binary number system
Modern imaging systems are at least 1024 x 1024
4096 x 4096 is being developed for digital radiography
Matrix = each cell corresponds to a specific location on the image
Pixel
Pixels
Digital Images ndash Bit Depth
bull Pixel values can be any bit depth (values from 0 to 1023)
bull Bit depth = or gray shades available for image display
bull Image contrast can be manipulated to stretched or contracted to alter the displayed contrast
bull Typically use ldquowindow widthrdquo and ldquowindow levelrdquo to alter displayed contrast and brightness
Digital - Grayscale
Bit depth Number of gray shades
available for display 8 bit 256 10 bit 1024 12 bit 4096 4 bit 16384
Display Bit Depth1 bit 6 bit 8 bit
2 shades 64 shades 256 shades
Computed Radiography As the plate is scanned ldquoreadrdquo data is collected
at a specific frequency = Sampling frequency
Spatial resolution determined by sampling frequency
With some systems the smaller IRrsquos have higher sampling frequencies amp more pixels per mm = more spatial resolution
Signal Loss (reducing image quality) Signal-to-Noise Ratio
Principle source of noise on the image is scatter radiation
Scattering of emitted light off screen
The efficiency of the photomultiplier tubes (PMTs) and photodiodes (PDs)
Improving Signal-to-Noise Ratio
Optical filter is used to prevent the longer-wavelength laser light affecting the image formation
Increasing exposure to IR Newer CR systems are better at reducing noise at lower exposure levels
Technique Selections
What are some factors that technologist must take into consideration when selecting a technique
What regulates that technologists to select appropriate techniques in FS CR amp DR
Screen Film
Self regulating system The receptor speed and film HampD curve defined
the proper exposure Achieving optimal OD guaranteed appropriate
exposure to the patient Over exposed = dark image Correct exposure = correct OD Under exposed = light image
Characteristic curveof radiographic film
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 32: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/32.jpg)
Needle PSP increase the absorption of x-rays and limit the spread of light emission
IP Design
Designed to optimize the intensity of light release (CE)
Enhance the absorption of x-rays (DQE)
Limit the spread of light emission for more detail
Photostimulable Luminescence When the cassette is put into the reader the
imaging plate is extracted and scanned With a helium laser beam or in more recent
systems solid-state laser diodes This beam about 100μm wide with a wavelength
of 633 nm (or 670 to 690 nm for solid state) Scans the plate with red light in a raster pattern
and gives energy to the trapped electrons
X-ray interaction with a PSP screen
1
2
X-ray interactions with the screen phosphors causes an e- to excited
When e- return to groundstate visible light is emitted
CR Phosphor PlatesCR Phosphor Plates
ABSORPTION EMISSION
X-RAY
LIGHT
LASER STIMULATION
ELECTRONTRAP
ELECTRONTRAP
CR Reader ndash PSP plate
Stimulates the matrix of trapped E- by a RED OR ULTRAVIOLET laser light
Trapped E- energy is released in a form of VIOLETBLUE light
Violet light is captured by PMT ndash is amplified and converted into a digital signal
Sequence of CR imaging
PMT
Beam deflector
LaserSource
Light channeling guide
Plate translation Sub-scan direction
Laser beam Scan direction
Output Signal
Reference detec tor
Beam splitter
Cylindrical m irrorf-thetalens
Amplifier
ADC
To imageprocessor
How CR works
Released light is captured by a PMT (photo
multiplier tube) An ultrasensitive photomultiplier tube or CCD (charged couple device)
PSP light is amplified by the PMT or CCD
This light is sent to the analog to digital converter (ADC) To convert light to binary
PMT (photomultiplier tube) The intensity (brightness) of the light ndash
correlates to the density on the image
So lots of light will correlate to what size number amp what color on the image
The digital numeric values are stored in matrix form called pixels for display on a cathode ray tube (CRT) or printed on film
ERASING THE SCREEN ~50 of trapped electrons released during ldquoreadrdquo After image is recorded Plate is erased with high intensity white light and
re-used Erasing should be done after every exposure or
at minimum every 24 hours to avoid ghosting on future images
Basics of Digital Images
bull digital images are a (matrix) of pixel (picture element) values
Pixels Digital images are made of discrete picture
elements arranged in a matrix The size of the image is described in the binary number system
Modern imaging systems are at least 1024 x 1024
4096 x 4096 is being developed for digital radiography
Matrix = each cell corresponds to a specific location on the image
Pixel
Pixels
Digital Images ndash Bit Depth
bull Pixel values can be any bit depth (values from 0 to 1023)
bull Bit depth = or gray shades available for image display
bull Image contrast can be manipulated to stretched or contracted to alter the displayed contrast
bull Typically use ldquowindow widthrdquo and ldquowindow levelrdquo to alter displayed contrast and brightness
Digital - Grayscale
Bit depth Number of gray shades
available for display 8 bit 256 10 bit 1024 12 bit 4096 4 bit 16384
Display Bit Depth1 bit 6 bit 8 bit
2 shades 64 shades 256 shades
Computed Radiography As the plate is scanned ldquoreadrdquo data is collected
at a specific frequency = Sampling frequency
Spatial resolution determined by sampling frequency
With some systems the smaller IRrsquos have higher sampling frequencies amp more pixels per mm = more spatial resolution
Signal Loss (reducing image quality) Signal-to-Noise Ratio
Principle source of noise on the image is scatter radiation
Scattering of emitted light off screen
The efficiency of the photomultiplier tubes (PMTs) and photodiodes (PDs)
Improving Signal-to-Noise Ratio
Optical filter is used to prevent the longer-wavelength laser light affecting the image formation
Increasing exposure to IR Newer CR systems are better at reducing noise at lower exposure levels
Technique Selections
What are some factors that technologist must take into consideration when selecting a technique
What regulates that technologists to select appropriate techniques in FS CR amp DR
Screen Film
Self regulating system The receptor speed and film HampD curve defined
the proper exposure Achieving optimal OD guaranteed appropriate
exposure to the patient Over exposed = dark image Correct exposure = correct OD Under exposed = light image
Characteristic curveof radiographic film
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 33: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/33.jpg)
IP Design
Designed to optimize the intensity of light release (CE)
Enhance the absorption of x-rays (DQE)
Limit the spread of light emission for more detail
Photostimulable Luminescence When the cassette is put into the reader the
imaging plate is extracted and scanned With a helium laser beam or in more recent
systems solid-state laser diodes This beam about 100μm wide with a wavelength
of 633 nm (or 670 to 690 nm for solid state) Scans the plate with red light in a raster pattern
and gives energy to the trapped electrons
X-ray interaction with a PSP screen
1
2
X-ray interactions with the screen phosphors causes an e- to excited
When e- return to groundstate visible light is emitted
CR Phosphor PlatesCR Phosphor Plates
ABSORPTION EMISSION
X-RAY
LIGHT
LASER STIMULATION
ELECTRONTRAP
ELECTRONTRAP
CR Reader ndash PSP plate
Stimulates the matrix of trapped E- by a RED OR ULTRAVIOLET laser light
Trapped E- energy is released in a form of VIOLETBLUE light
Violet light is captured by PMT ndash is amplified and converted into a digital signal
Sequence of CR imaging
PMT
Beam deflector
LaserSource
Light channeling guide
Plate translation Sub-scan direction
Laser beam Scan direction
Output Signal
Reference detec tor
Beam splitter
Cylindrical m irrorf-thetalens
Amplifier
ADC
To imageprocessor
How CR works
Released light is captured by a PMT (photo
multiplier tube) An ultrasensitive photomultiplier tube or CCD (charged couple device)
PSP light is amplified by the PMT or CCD
This light is sent to the analog to digital converter (ADC) To convert light to binary
PMT (photomultiplier tube) The intensity (brightness) of the light ndash
correlates to the density on the image
So lots of light will correlate to what size number amp what color on the image
The digital numeric values are stored in matrix form called pixels for display on a cathode ray tube (CRT) or printed on film
ERASING THE SCREEN ~50 of trapped electrons released during ldquoreadrdquo After image is recorded Plate is erased with high intensity white light and
re-used Erasing should be done after every exposure or
at minimum every 24 hours to avoid ghosting on future images
Basics of Digital Images
bull digital images are a (matrix) of pixel (picture element) values
Pixels Digital images are made of discrete picture
elements arranged in a matrix The size of the image is described in the binary number system
Modern imaging systems are at least 1024 x 1024
4096 x 4096 is being developed for digital radiography
Matrix = each cell corresponds to a specific location on the image
Pixel
Pixels
Digital Images ndash Bit Depth
bull Pixel values can be any bit depth (values from 0 to 1023)
bull Bit depth = or gray shades available for image display
bull Image contrast can be manipulated to stretched or contracted to alter the displayed contrast
bull Typically use ldquowindow widthrdquo and ldquowindow levelrdquo to alter displayed contrast and brightness
Digital - Grayscale
Bit depth Number of gray shades
available for display 8 bit 256 10 bit 1024 12 bit 4096 4 bit 16384
Display Bit Depth1 bit 6 bit 8 bit
2 shades 64 shades 256 shades
Computed Radiography As the plate is scanned ldquoreadrdquo data is collected
at a specific frequency = Sampling frequency
Spatial resolution determined by sampling frequency
With some systems the smaller IRrsquos have higher sampling frequencies amp more pixels per mm = more spatial resolution
Signal Loss (reducing image quality) Signal-to-Noise Ratio
Principle source of noise on the image is scatter radiation
Scattering of emitted light off screen
The efficiency of the photomultiplier tubes (PMTs) and photodiodes (PDs)
Improving Signal-to-Noise Ratio
Optical filter is used to prevent the longer-wavelength laser light affecting the image formation
Increasing exposure to IR Newer CR systems are better at reducing noise at lower exposure levels
Technique Selections
What are some factors that technologist must take into consideration when selecting a technique
What regulates that technologists to select appropriate techniques in FS CR amp DR
Screen Film
Self regulating system The receptor speed and film HampD curve defined
the proper exposure Achieving optimal OD guaranteed appropriate
exposure to the patient Over exposed = dark image Correct exposure = correct OD Under exposed = light image
Characteristic curveof radiographic film
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 34: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/34.jpg)
Photostimulable Luminescence When the cassette is put into the reader the
imaging plate is extracted and scanned With a helium laser beam or in more recent
systems solid-state laser diodes This beam about 100μm wide with a wavelength
of 633 nm (or 670 to 690 nm for solid state) Scans the plate with red light in a raster pattern
and gives energy to the trapped electrons
X-ray interaction with a PSP screen
1
2
X-ray interactions with the screen phosphors causes an e- to excited
When e- return to groundstate visible light is emitted
CR Phosphor PlatesCR Phosphor Plates
ABSORPTION EMISSION
X-RAY
LIGHT
LASER STIMULATION
ELECTRONTRAP
ELECTRONTRAP
CR Reader ndash PSP plate
Stimulates the matrix of trapped E- by a RED OR ULTRAVIOLET laser light
Trapped E- energy is released in a form of VIOLETBLUE light
Violet light is captured by PMT ndash is amplified and converted into a digital signal
Sequence of CR imaging
PMT
Beam deflector
LaserSource
Light channeling guide
Plate translation Sub-scan direction
Laser beam Scan direction
Output Signal
Reference detec tor
Beam splitter
Cylindrical m irrorf-thetalens
Amplifier
ADC
To imageprocessor
How CR works
Released light is captured by a PMT (photo
multiplier tube) An ultrasensitive photomultiplier tube or CCD (charged couple device)
PSP light is amplified by the PMT or CCD
This light is sent to the analog to digital converter (ADC) To convert light to binary
PMT (photomultiplier tube) The intensity (brightness) of the light ndash
correlates to the density on the image
So lots of light will correlate to what size number amp what color on the image
The digital numeric values are stored in matrix form called pixels for display on a cathode ray tube (CRT) or printed on film
ERASING THE SCREEN ~50 of trapped electrons released during ldquoreadrdquo After image is recorded Plate is erased with high intensity white light and
re-used Erasing should be done after every exposure or
at minimum every 24 hours to avoid ghosting on future images
Basics of Digital Images
bull digital images are a (matrix) of pixel (picture element) values
Pixels Digital images are made of discrete picture
elements arranged in a matrix The size of the image is described in the binary number system
Modern imaging systems are at least 1024 x 1024
4096 x 4096 is being developed for digital radiography
Matrix = each cell corresponds to a specific location on the image
Pixel
Pixels
Digital Images ndash Bit Depth
bull Pixel values can be any bit depth (values from 0 to 1023)
bull Bit depth = or gray shades available for image display
bull Image contrast can be manipulated to stretched or contracted to alter the displayed contrast
bull Typically use ldquowindow widthrdquo and ldquowindow levelrdquo to alter displayed contrast and brightness
Digital - Grayscale
Bit depth Number of gray shades
available for display 8 bit 256 10 bit 1024 12 bit 4096 4 bit 16384
Display Bit Depth1 bit 6 bit 8 bit
2 shades 64 shades 256 shades
Computed Radiography As the plate is scanned ldquoreadrdquo data is collected
at a specific frequency = Sampling frequency
Spatial resolution determined by sampling frequency
With some systems the smaller IRrsquos have higher sampling frequencies amp more pixels per mm = more spatial resolution
Signal Loss (reducing image quality) Signal-to-Noise Ratio
Principle source of noise on the image is scatter radiation
Scattering of emitted light off screen
The efficiency of the photomultiplier tubes (PMTs) and photodiodes (PDs)
Improving Signal-to-Noise Ratio
Optical filter is used to prevent the longer-wavelength laser light affecting the image formation
Increasing exposure to IR Newer CR systems are better at reducing noise at lower exposure levels
Technique Selections
What are some factors that technologist must take into consideration when selecting a technique
What regulates that technologists to select appropriate techniques in FS CR amp DR
Screen Film
Self regulating system The receptor speed and film HampD curve defined
the proper exposure Achieving optimal OD guaranteed appropriate
exposure to the patient Over exposed = dark image Correct exposure = correct OD Under exposed = light image
Characteristic curveof radiographic film
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 35: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/35.jpg)
X-ray interaction with a PSP screen
1
2
X-ray interactions with the screen phosphors causes an e- to excited
When e- return to groundstate visible light is emitted
CR Phosphor PlatesCR Phosphor Plates
ABSORPTION EMISSION
X-RAY
LIGHT
LASER STIMULATION
ELECTRONTRAP
ELECTRONTRAP
CR Reader ndash PSP plate
Stimulates the matrix of trapped E- by a RED OR ULTRAVIOLET laser light
Trapped E- energy is released in a form of VIOLETBLUE light
Violet light is captured by PMT ndash is amplified and converted into a digital signal
Sequence of CR imaging
PMT
Beam deflector
LaserSource
Light channeling guide
Plate translation Sub-scan direction
Laser beam Scan direction
Output Signal
Reference detec tor
Beam splitter
Cylindrical m irrorf-thetalens
Amplifier
ADC
To imageprocessor
How CR works
Released light is captured by a PMT (photo
multiplier tube) An ultrasensitive photomultiplier tube or CCD (charged couple device)
PSP light is amplified by the PMT or CCD
This light is sent to the analog to digital converter (ADC) To convert light to binary
PMT (photomultiplier tube) The intensity (brightness) of the light ndash
correlates to the density on the image
So lots of light will correlate to what size number amp what color on the image
The digital numeric values are stored in matrix form called pixels for display on a cathode ray tube (CRT) or printed on film
ERASING THE SCREEN ~50 of trapped electrons released during ldquoreadrdquo After image is recorded Plate is erased with high intensity white light and
re-used Erasing should be done after every exposure or
at minimum every 24 hours to avoid ghosting on future images
Basics of Digital Images
bull digital images are a (matrix) of pixel (picture element) values
Pixels Digital images are made of discrete picture
elements arranged in a matrix The size of the image is described in the binary number system
Modern imaging systems are at least 1024 x 1024
4096 x 4096 is being developed for digital radiography
Matrix = each cell corresponds to a specific location on the image
Pixel
Pixels
Digital Images ndash Bit Depth
bull Pixel values can be any bit depth (values from 0 to 1023)
bull Bit depth = or gray shades available for image display
bull Image contrast can be manipulated to stretched or contracted to alter the displayed contrast
bull Typically use ldquowindow widthrdquo and ldquowindow levelrdquo to alter displayed contrast and brightness
Digital - Grayscale
Bit depth Number of gray shades
available for display 8 bit 256 10 bit 1024 12 bit 4096 4 bit 16384
Display Bit Depth1 bit 6 bit 8 bit
2 shades 64 shades 256 shades
Computed Radiography As the plate is scanned ldquoreadrdquo data is collected
at a specific frequency = Sampling frequency
Spatial resolution determined by sampling frequency
With some systems the smaller IRrsquos have higher sampling frequencies amp more pixels per mm = more spatial resolution
Signal Loss (reducing image quality) Signal-to-Noise Ratio
Principle source of noise on the image is scatter radiation
Scattering of emitted light off screen
The efficiency of the photomultiplier tubes (PMTs) and photodiodes (PDs)
Improving Signal-to-Noise Ratio
Optical filter is used to prevent the longer-wavelength laser light affecting the image formation
Increasing exposure to IR Newer CR systems are better at reducing noise at lower exposure levels
Technique Selections
What are some factors that technologist must take into consideration when selecting a technique
What regulates that technologists to select appropriate techniques in FS CR amp DR
Screen Film
Self regulating system The receptor speed and film HampD curve defined
the proper exposure Achieving optimal OD guaranteed appropriate
exposure to the patient Over exposed = dark image Correct exposure = correct OD Under exposed = light image
Characteristic curveof radiographic film
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 36: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/36.jpg)
CR Phosphor PlatesCR Phosphor Plates
ABSORPTION EMISSION
X-RAY
LIGHT
LASER STIMULATION
ELECTRONTRAP
ELECTRONTRAP
CR Reader ndash PSP plate
Stimulates the matrix of trapped E- by a RED OR ULTRAVIOLET laser light
Trapped E- energy is released in a form of VIOLETBLUE light
Violet light is captured by PMT ndash is amplified and converted into a digital signal
Sequence of CR imaging
PMT
Beam deflector
LaserSource
Light channeling guide
Plate translation Sub-scan direction
Laser beam Scan direction
Output Signal
Reference detec tor
Beam splitter
Cylindrical m irrorf-thetalens
Amplifier
ADC
To imageprocessor
How CR works
Released light is captured by a PMT (photo
multiplier tube) An ultrasensitive photomultiplier tube or CCD (charged couple device)
PSP light is amplified by the PMT or CCD
This light is sent to the analog to digital converter (ADC) To convert light to binary
PMT (photomultiplier tube) The intensity (brightness) of the light ndash
correlates to the density on the image
So lots of light will correlate to what size number amp what color on the image
The digital numeric values are stored in matrix form called pixels for display on a cathode ray tube (CRT) or printed on film
ERASING THE SCREEN ~50 of trapped electrons released during ldquoreadrdquo After image is recorded Plate is erased with high intensity white light and
re-used Erasing should be done after every exposure or
at minimum every 24 hours to avoid ghosting on future images
Basics of Digital Images
bull digital images are a (matrix) of pixel (picture element) values
Pixels Digital images are made of discrete picture
elements arranged in a matrix The size of the image is described in the binary number system
Modern imaging systems are at least 1024 x 1024
4096 x 4096 is being developed for digital radiography
Matrix = each cell corresponds to a specific location on the image
Pixel
Pixels
Digital Images ndash Bit Depth
bull Pixel values can be any bit depth (values from 0 to 1023)
bull Bit depth = or gray shades available for image display
bull Image contrast can be manipulated to stretched or contracted to alter the displayed contrast
bull Typically use ldquowindow widthrdquo and ldquowindow levelrdquo to alter displayed contrast and brightness
Digital - Grayscale
Bit depth Number of gray shades
available for display 8 bit 256 10 bit 1024 12 bit 4096 4 bit 16384
Display Bit Depth1 bit 6 bit 8 bit
2 shades 64 shades 256 shades
Computed Radiography As the plate is scanned ldquoreadrdquo data is collected
at a specific frequency = Sampling frequency
Spatial resolution determined by sampling frequency
With some systems the smaller IRrsquos have higher sampling frequencies amp more pixels per mm = more spatial resolution
Signal Loss (reducing image quality) Signal-to-Noise Ratio
Principle source of noise on the image is scatter radiation
Scattering of emitted light off screen
The efficiency of the photomultiplier tubes (PMTs) and photodiodes (PDs)
Improving Signal-to-Noise Ratio
Optical filter is used to prevent the longer-wavelength laser light affecting the image formation
Increasing exposure to IR Newer CR systems are better at reducing noise at lower exposure levels
Technique Selections
What are some factors that technologist must take into consideration when selecting a technique
What regulates that technologists to select appropriate techniques in FS CR amp DR
Screen Film
Self regulating system The receptor speed and film HampD curve defined
the proper exposure Achieving optimal OD guaranteed appropriate
exposure to the patient Over exposed = dark image Correct exposure = correct OD Under exposed = light image
Characteristic curveof radiographic film
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 37: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/37.jpg)
CR Reader ndash PSP plate
Stimulates the matrix of trapped E- by a RED OR ULTRAVIOLET laser light
Trapped E- energy is released in a form of VIOLETBLUE light
Violet light is captured by PMT ndash is amplified and converted into a digital signal
Sequence of CR imaging
PMT
Beam deflector
LaserSource
Light channeling guide
Plate translation Sub-scan direction
Laser beam Scan direction
Output Signal
Reference detec tor
Beam splitter
Cylindrical m irrorf-thetalens
Amplifier
ADC
To imageprocessor
How CR works
Released light is captured by a PMT (photo
multiplier tube) An ultrasensitive photomultiplier tube or CCD (charged couple device)
PSP light is amplified by the PMT or CCD
This light is sent to the analog to digital converter (ADC) To convert light to binary
PMT (photomultiplier tube) The intensity (brightness) of the light ndash
correlates to the density on the image
So lots of light will correlate to what size number amp what color on the image
The digital numeric values are stored in matrix form called pixels for display on a cathode ray tube (CRT) or printed on film
ERASING THE SCREEN ~50 of trapped electrons released during ldquoreadrdquo After image is recorded Plate is erased with high intensity white light and
re-used Erasing should be done after every exposure or
at minimum every 24 hours to avoid ghosting on future images
Basics of Digital Images
bull digital images are a (matrix) of pixel (picture element) values
Pixels Digital images are made of discrete picture
elements arranged in a matrix The size of the image is described in the binary number system
Modern imaging systems are at least 1024 x 1024
4096 x 4096 is being developed for digital radiography
Matrix = each cell corresponds to a specific location on the image
Pixel
Pixels
Digital Images ndash Bit Depth
bull Pixel values can be any bit depth (values from 0 to 1023)
bull Bit depth = or gray shades available for image display
bull Image contrast can be manipulated to stretched or contracted to alter the displayed contrast
bull Typically use ldquowindow widthrdquo and ldquowindow levelrdquo to alter displayed contrast and brightness
Digital - Grayscale
Bit depth Number of gray shades
available for display 8 bit 256 10 bit 1024 12 bit 4096 4 bit 16384
Display Bit Depth1 bit 6 bit 8 bit
2 shades 64 shades 256 shades
Computed Radiography As the plate is scanned ldquoreadrdquo data is collected
at a specific frequency = Sampling frequency
Spatial resolution determined by sampling frequency
With some systems the smaller IRrsquos have higher sampling frequencies amp more pixels per mm = more spatial resolution
Signal Loss (reducing image quality) Signal-to-Noise Ratio
Principle source of noise on the image is scatter radiation
Scattering of emitted light off screen
The efficiency of the photomultiplier tubes (PMTs) and photodiodes (PDs)
Improving Signal-to-Noise Ratio
Optical filter is used to prevent the longer-wavelength laser light affecting the image formation
Increasing exposure to IR Newer CR systems are better at reducing noise at lower exposure levels
Technique Selections
What are some factors that technologist must take into consideration when selecting a technique
What regulates that technologists to select appropriate techniques in FS CR amp DR
Screen Film
Self regulating system The receptor speed and film HampD curve defined
the proper exposure Achieving optimal OD guaranteed appropriate
exposure to the patient Over exposed = dark image Correct exposure = correct OD Under exposed = light image
Characteristic curveof radiographic film
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 38: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/38.jpg)
Sequence of CR imaging
PMT
Beam deflector
LaserSource
Light channeling guide
Plate translation Sub-scan direction
Laser beam Scan direction
Output Signal
Reference detec tor
Beam splitter
Cylindrical m irrorf-thetalens
Amplifier
ADC
To imageprocessor
How CR works
Released light is captured by a PMT (photo
multiplier tube) An ultrasensitive photomultiplier tube or CCD (charged couple device)
PSP light is amplified by the PMT or CCD
This light is sent to the analog to digital converter (ADC) To convert light to binary
PMT (photomultiplier tube) The intensity (brightness) of the light ndash
correlates to the density on the image
So lots of light will correlate to what size number amp what color on the image
The digital numeric values are stored in matrix form called pixels for display on a cathode ray tube (CRT) or printed on film
ERASING THE SCREEN ~50 of trapped electrons released during ldquoreadrdquo After image is recorded Plate is erased with high intensity white light and
re-used Erasing should be done after every exposure or
at minimum every 24 hours to avoid ghosting on future images
Basics of Digital Images
bull digital images are a (matrix) of pixel (picture element) values
Pixels Digital images are made of discrete picture
elements arranged in a matrix The size of the image is described in the binary number system
Modern imaging systems are at least 1024 x 1024
4096 x 4096 is being developed for digital radiography
Matrix = each cell corresponds to a specific location on the image
Pixel
Pixels
Digital Images ndash Bit Depth
bull Pixel values can be any bit depth (values from 0 to 1023)
bull Bit depth = or gray shades available for image display
bull Image contrast can be manipulated to stretched or contracted to alter the displayed contrast
bull Typically use ldquowindow widthrdquo and ldquowindow levelrdquo to alter displayed contrast and brightness
Digital - Grayscale
Bit depth Number of gray shades
available for display 8 bit 256 10 bit 1024 12 bit 4096 4 bit 16384
Display Bit Depth1 bit 6 bit 8 bit
2 shades 64 shades 256 shades
Computed Radiography As the plate is scanned ldquoreadrdquo data is collected
at a specific frequency = Sampling frequency
Spatial resolution determined by sampling frequency
With some systems the smaller IRrsquos have higher sampling frequencies amp more pixels per mm = more spatial resolution
Signal Loss (reducing image quality) Signal-to-Noise Ratio
Principle source of noise on the image is scatter radiation
Scattering of emitted light off screen
The efficiency of the photomultiplier tubes (PMTs) and photodiodes (PDs)
Improving Signal-to-Noise Ratio
Optical filter is used to prevent the longer-wavelength laser light affecting the image formation
Increasing exposure to IR Newer CR systems are better at reducing noise at lower exposure levels
Technique Selections
What are some factors that technologist must take into consideration when selecting a technique
What regulates that technologists to select appropriate techniques in FS CR amp DR
Screen Film
Self regulating system The receptor speed and film HampD curve defined
the proper exposure Achieving optimal OD guaranteed appropriate
exposure to the patient Over exposed = dark image Correct exposure = correct OD Under exposed = light image
Characteristic curveof radiographic film
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 39: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/39.jpg)
PMT
Beam deflector
LaserSource
Light channeling guide
Plate translation Sub-scan direction
Laser beam Scan direction
Output Signal
Reference detec tor
Beam splitter
Cylindrical m irrorf-thetalens
Amplifier
ADC
To imageprocessor
How CR works
Released light is captured by a PMT (photo
multiplier tube) An ultrasensitive photomultiplier tube or CCD (charged couple device)
PSP light is amplified by the PMT or CCD
This light is sent to the analog to digital converter (ADC) To convert light to binary
PMT (photomultiplier tube) The intensity (brightness) of the light ndash
correlates to the density on the image
So lots of light will correlate to what size number amp what color on the image
The digital numeric values are stored in matrix form called pixels for display on a cathode ray tube (CRT) or printed on film
ERASING THE SCREEN ~50 of trapped electrons released during ldquoreadrdquo After image is recorded Plate is erased with high intensity white light and
re-used Erasing should be done after every exposure or
at minimum every 24 hours to avoid ghosting on future images
Basics of Digital Images
bull digital images are a (matrix) of pixel (picture element) values
Pixels Digital images are made of discrete picture
elements arranged in a matrix The size of the image is described in the binary number system
Modern imaging systems are at least 1024 x 1024
4096 x 4096 is being developed for digital radiography
Matrix = each cell corresponds to a specific location on the image
Pixel
Pixels
Digital Images ndash Bit Depth
bull Pixel values can be any bit depth (values from 0 to 1023)
bull Bit depth = or gray shades available for image display
bull Image contrast can be manipulated to stretched or contracted to alter the displayed contrast
bull Typically use ldquowindow widthrdquo and ldquowindow levelrdquo to alter displayed contrast and brightness
Digital - Grayscale
Bit depth Number of gray shades
available for display 8 bit 256 10 bit 1024 12 bit 4096 4 bit 16384
Display Bit Depth1 bit 6 bit 8 bit
2 shades 64 shades 256 shades
Computed Radiography As the plate is scanned ldquoreadrdquo data is collected
at a specific frequency = Sampling frequency
Spatial resolution determined by sampling frequency
With some systems the smaller IRrsquos have higher sampling frequencies amp more pixels per mm = more spatial resolution
Signal Loss (reducing image quality) Signal-to-Noise Ratio
Principle source of noise on the image is scatter radiation
Scattering of emitted light off screen
The efficiency of the photomultiplier tubes (PMTs) and photodiodes (PDs)
Improving Signal-to-Noise Ratio
Optical filter is used to prevent the longer-wavelength laser light affecting the image formation
Increasing exposure to IR Newer CR systems are better at reducing noise at lower exposure levels
Technique Selections
What are some factors that technologist must take into consideration when selecting a technique
What regulates that technologists to select appropriate techniques in FS CR amp DR
Screen Film
Self regulating system The receptor speed and film HampD curve defined
the proper exposure Achieving optimal OD guaranteed appropriate
exposure to the patient Over exposed = dark image Correct exposure = correct OD Under exposed = light image
Characteristic curveof radiographic film
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 40: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/40.jpg)
How CR works
Released light is captured by a PMT (photo
multiplier tube) An ultrasensitive photomultiplier tube or CCD (charged couple device)
PSP light is amplified by the PMT or CCD
This light is sent to the analog to digital converter (ADC) To convert light to binary
PMT (photomultiplier tube) The intensity (brightness) of the light ndash
correlates to the density on the image
So lots of light will correlate to what size number amp what color on the image
The digital numeric values are stored in matrix form called pixels for display on a cathode ray tube (CRT) or printed on film
ERASING THE SCREEN ~50 of trapped electrons released during ldquoreadrdquo After image is recorded Plate is erased with high intensity white light and
re-used Erasing should be done after every exposure or
at minimum every 24 hours to avoid ghosting on future images
Basics of Digital Images
bull digital images are a (matrix) of pixel (picture element) values
Pixels Digital images are made of discrete picture
elements arranged in a matrix The size of the image is described in the binary number system
Modern imaging systems are at least 1024 x 1024
4096 x 4096 is being developed for digital radiography
Matrix = each cell corresponds to a specific location on the image
Pixel
Pixels
Digital Images ndash Bit Depth
bull Pixel values can be any bit depth (values from 0 to 1023)
bull Bit depth = or gray shades available for image display
bull Image contrast can be manipulated to stretched or contracted to alter the displayed contrast
bull Typically use ldquowindow widthrdquo and ldquowindow levelrdquo to alter displayed contrast and brightness
Digital - Grayscale
Bit depth Number of gray shades
available for display 8 bit 256 10 bit 1024 12 bit 4096 4 bit 16384
Display Bit Depth1 bit 6 bit 8 bit
2 shades 64 shades 256 shades
Computed Radiography As the plate is scanned ldquoreadrdquo data is collected
at a specific frequency = Sampling frequency
Spatial resolution determined by sampling frequency
With some systems the smaller IRrsquos have higher sampling frequencies amp more pixels per mm = more spatial resolution
Signal Loss (reducing image quality) Signal-to-Noise Ratio
Principle source of noise on the image is scatter radiation
Scattering of emitted light off screen
The efficiency of the photomultiplier tubes (PMTs) and photodiodes (PDs)
Improving Signal-to-Noise Ratio
Optical filter is used to prevent the longer-wavelength laser light affecting the image formation
Increasing exposure to IR Newer CR systems are better at reducing noise at lower exposure levels
Technique Selections
What are some factors that technologist must take into consideration when selecting a technique
What regulates that technologists to select appropriate techniques in FS CR amp DR
Screen Film
Self regulating system The receptor speed and film HampD curve defined
the proper exposure Achieving optimal OD guaranteed appropriate
exposure to the patient Over exposed = dark image Correct exposure = correct OD Under exposed = light image
Characteristic curveof radiographic film
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 41: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/41.jpg)
PMT (photomultiplier tube) The intensity (brightness) of the light ndash
correlates to the density on the image
So lots of light will correlate to what size number amp what color on the image
The digital numeric values are stored in matrix form called pixels for display on a cathode ray tube (CRT) or printed on film
ERASING THE SCREEN ~50 of trapped electrons released during ldquoreadrdquo After image is recorded Plate is erased with high intensity white light and
re-used Erasing should be done after every exposure or
at minimum every 24 hours to avoid ghosting on future images
Basics of Digital Images
bull digital images are a (matrix) of pixel (picture element) values
Pixels Digital images are made of discrete picture
elements arranged in a matrix The size of the image is described in the binary number system
Modern imaging systems are at least 1024 x 1024
4096 x 4096 is being developed for digital radiography
Matrix = each cell corresponds to a specific location on the image
Pixel
Pixels
Digital Images ndash Bit Depth
bull Pixel values can be any bit depth (values from 0 to 1023)
bull Bit depth = or gray shades available for image display
bull Image contrast can be manipulated to stretched or contracted to alter the displayed contrast
bull Typically use ldquowindow widthrdquo and ldquowindow levelrdquo to alter displayed contrast and brightness
Digital - Grayscale
Bit depth Number of gray shades
available for display 8 bit 256 10 bit 1024 12 bit 4096 4 bit 16384
Display Bit Depth1 bit 6 bit 8 bit
2 shades 64 shades 256 shades
Computed Radiography As the plate is scanned ldquoreadrdquo data is collected
at a specific frequency = Sampling frequency
Spatial resolution determined by sampling frequency
With some systems the smaller IRrsquos have higher sampling frequencies amp more pixels per mm = more spatial resolution
Signal Loss (reducing image quality) Signal-to-Noise Ratio
Principle source of noise on the image is scatter radiation
Scattering of emitted light off screen
The efficiency of the photomultiplier tubes (PMTs) and photodiodes (PDs)
Improving Signal-to-Noise Ratio
Optical filter is used to prevent the longer-wavelength laser light affecting the image formation
Increasing exposure to IR Newer CR systems are better at reducing noise at lower exposure levels
Technique Selections
What are some factors that technologist must take into consideration when selecting a technique
What regulates that technologists to select appropriate techniques in FS CR amp DR
Screen Film
Self regulating system The receptor speed and film HampD curve defined
the proper exposure Achieving optimal OD guaranteed appropriate
exposure to the patient Over exposed = dark image Correct exposure = correct OD Under exposed = light image
Characteristic curveof radiographic film
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 42: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/42.jpg)
ERASING THE SCREEN ~50 of trapped electrons released during ldquoreadrdquo After image is recorded Plate is erased with high intensity white light and
re-used Erasing should be done after every exposure or
at minimum every 24 hours to avoid ghosting on future images
Basics of Digital Images
bull digital images are a (matrix) of pixel (picture element) values
Pixels Digital images are made of discrete picture
elements arranged in a matrix The size of the image is described in the binary number system
Modern imaging systems are at least 1024 x 1024
4096 x 4096 is being developed for digital radiography
Matrix = each cell corresponds to a specific location on the image
Pixel
Pixels
Digital Images ndash Bit Depth
bull Pixel values can be any bit depth (values from 0 to 1023)
bull Bit depth = or gray shades available for image display
bull Image contrast can be manipulated to stretched or contracted to alter the displayed contrast
bull Typically use ldquowindow widthrdquo and ldquowindow levelrdquo to alter displayed contrast and brightness
Digital - Grayscale
Bit depth Number of gray shades
available for display 8 bit 256 10 bit 1024 12 bit 4096 4 bit 16384
Display Bit Depth1 bit 6 bit 8 bit
2 shades 64 shades 256 shades
Computed Radiography As the plate is scanned ldquoreadrdquo data is collected
at a specific frequency = Sampling frequency
Spatial resolution determined by sampling frequency
With some systems the smaller IRrsquos have higher sampling frequencies amp more pixels per mm = more spatial resolution
Signal Loss (reducing image quality) Signal-to-Noise Ratio
Principle source of noise on the image is scatter radiation
Scattering of emitted light off screen
The efficiency of the photomultiplier tubes (PMTs) and photodiodes (PDs)
Improving Signal-to-Noise Ratio
Optical filter is used to prevent the longer-wavelength laser light affecting the image formation
Increasing exposure to IR Newer CR systems are better at reducing noise at lower exposure levels
Technique Selections
What are some factors that technologist must take into consideration when selecting a technique
What regulates that technologists to select appropriate techniques in FS CR amp DR
Screen Film
Self regulating system The receptor speed and film HampD curve defined
the proper exposure Achieving optimal OD guaranteed appropriate
exposure to the patient Over exposed = dark image Correct exposure = correct OD Under exposed = light image
Characteristic curveof radiographic film
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 43: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/43.jpg)
Basics of Digital Images
bull digital images are a (matrix) of pixel (picture element) values
Pixels Digital images are made of discrete picture
elements arranged in a matrix The size of the image is described in the binary number system
Modern imaging systems are at least 1024 x 1024
4096 x 4096 is being developed for digital radiography
Matrix = each cell corresponds to a specific location on the image
Pixel
Pixels
Digital Images ndash Bit Depth
bull Pixel values can be any bit depth (values from 0 to 1023)
bull Bit depth = or gray shades available for image display
bull Image contrast can be manipulated to stretched or contracted to alter the displayed contrast
bull Typically use ldquowindow widthrdquo and ldquowindow levelrdquo to alter displayed contrast and brightness
Digital - Grayscale
Bit depth Number of gray shades
available for display 8 bit 256 10 bit 1024 12 bit 4096 4 bit 16384
Display Bit Depth1 bit 6 bit 8 bit
2 shades 64 shades 256 shades
Computed Radiography As the plate is scanned ldquoreadrdquo data is collected
at a specific frequency = Sampling frequency
Spatial resolution determined by sampling frequency
With some systems the smaller IRrsquos have higher sampling frequencies amp more pixels per mm = more spatial resolution
Signal Loss (reducing image quality) Signal-to-Noise Ratio
Principle source of noise on the image is scatter radiation
Scattering of emitted light off screen
The efficiency of the photomultiplier tubes (PMTs) and photodiodes (PDs)
Improving Signal-to-Noise Ratio
Optical filter is used to prevent the longer-wavelength laser light affecting the image formation
Increasing exposure to IR Newer CR systems are better at reducing noise at lower exposure levels
Technique Selections
What are some factors that technologist must take into consideration when selecting a technique
What regulates that technologists to select appropriate techniques in FS CR amp DR
Screen Film
Self regulating system The receptor speed and film HampD curve defined
the proper exposure Achieving optimal OD guaranteed appropriate
exposure to the patient Over exposed = dark image Correct exposure = correct OD Under exposed = light image
Characteristic curveof radiographic film
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 44: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/44.jpg)
Pixels Digital images are made of discrete picture
elements arranged in a matrix The size of the image is described in the binary number system
Modern imaging systems are at least 1024 x 1024
4096 x 4096 is being developed for digital radiography
Matrix = each cell corresponds to a specific location on the image
Pixel
Pixels
Digital Images ndash Bit Depth
bull Pixel values can be any bit depth (values from 0 to 1023)
bull Bit depth = or gray shades available for image display
bull Image contrast can be manipulated to stretched or contracted to alter the displayed contrast
bull Typically use ldquowindow widthrdquo and ldquowindow levelrdquo to alter displayed contrast and brightness
Digital - Grayscale
Bit depth Number of gray shades
available for display 8 bit 256 10 bit 1024 12 bit 4096 4 bit 16384
Display Bit Depth1 bit 6 bit 8 bit
2 shades 64 shades 256 shades
Computed Radiography As the plate is scanned ldquoreadrdquo data is collected
at a specific frequency = Sampling frequency
Spatial resolution determined by sampling frequency
With some systems the smaller IRrsquos have higher sampling frequencies amp more pixels per mm = more spatial resolution
Signal Loss (reducing image quality) Signal-to-Noise Ratio
Principle source of noise on the image is scatter radiation
Scattering of emitted light off screen
The efficiency of the photomultiplier tubes (PMTs) and photodiodes (PDs)
Improving Signal-to-Noise Ratio
Optical filter is used to prevent the longer-wavelength laser light affecting the image formation
Increasing exposure to IR Newer CR systems are better at reducing noise at lower exposure levels
Technique Selections
What are some factors that technologist must take into consideration when selecting a technique
What regulates that technologists to select appropriate techniques in FS CR amp DR
Screen Film
Self regulating system The receptor speed and film HampD curve defined
the proper exposure Achieving optimal OD guaranteed appropriate
exposure to the patient Over exposed = dark image Correct exposure = correct OD Under exposed = light image
Characteristic curveof radiographic film
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 45: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/45.jpg)
Matrix = each cell corresponds to a specific location on the image
Pixel
Pixels
Digital Images ndash Bit Depth
bull Pixel values can be any bit depth (values from 0 to 1023)
bull Bit depth = or gray shades available for image display
bull Image contrast can be manipulated to stretched or contracted to alter the displayed contrast
bull Typically use ldquowindow widthrdquo and ldquowindow levelrdquo to alter displayed contrast and brightness
Digital - Grayscale
Bit depth Number of gray shades
available for display 8 bit 256 10 bit 1024 12 bit 4096 4 bit 16384
Display Bit Depth1 bit 6 bit 8 bit
2 shades 64 shades 256 shades
Computed Radiography As the plate is scanned ldquoreadrdquo data is collected
at a specific frequency = Sampling frequency
Spatial resolution determined by sampling frequency
With some systems the smaller IRrsquos have higher sampling frequencies amp more pixels per mm = more spatial resolution
Signal Loss (reducing image quality) Signal-to-Noise Ratio
Principle source of noise on the image is scatter radiation
Scattering of emitted light off screen
The efficiency of the photomultiplier tubes (PMTs) and photodiodes (PDs)
Improving Signal-to-Noise Ratio
Optical filter is used to prevent the longer-wavelength laser light affecting the image formation
Increasing exposure to IR Newer CR systems are better at reducing noise at lower exposure levels
Technique Selections
What are some factors that technologist must take into consideration when selecting a technique
What regulates that technologists to select appropriate techniques in FS CR amp DR
Screen Film
Self regulating system The receptor speed and film HampD curve defined
the proper exposure Achieving optimal OD guaranteed appropriate
exposure to the patient Over exposed = dark image Correct exposure = correct OD Under exposed = light image
Characteristic curveof radiographic film
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 46: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/46.jpg)
Pixel
Pixels
Digital Images ndash Bit Depth
bull Pixel values can be any bit depth (values from 0 to 1023)
bull Bit depth = or gray shades available for image display
bull Image contrast can be manipulated to stretched or contracted to alter the displayed contrast
bull Typically use ldquowindow widthrdquo and ldquowindow levelrdquo to alter displayed contrast and brightness
Digital - Grayscale
Bit depth Number of gray shades
available for display 8 bit 256 10 bit 1024 12 bit 4096 4 bit 16384
Display Bit Depth1 bit 6 bit 8 bit
2 shades 64 shades 256 shades
Computed Radiography As the plate is scanned ldquoreadrdquo data is collected
at a specific frequency = Sampling frequency
Spatial resolution determined by sampling frequency
With some systems the smaller IRrsquos have higher sampling frequencies amp more pixels per mm = more spatial resolution
Signal Loss (reducing image quality) Signal-to-Noise Ratio
Principle source of noise on the image is scatter radiation
Scattering of emitted light off screen
The efficiency of the photomultiplier tubes (PMTs) and photodiodes (PDs)
Improving Signal-to-Noise Ratio
Optical filter is used to prevent the longer-wavelength laser light affecting the image formation
Increasing exposure to IR Newer CR systems are better at reducing noise at lower exposure levels
Technique Selections
What are some factors that technologist must take into consideration when selecting a technique
What regulates that technologists to select appropriate techniques in FS CR amp DR
Screen Film
Self regulating system The receptor speed and film HampD curve defined
the proper exposure Achieving optimal OD guaranteed appropriate
exposure to the patient Over exposed = dark image Correct exposure = correct OD Under exposed = light image
Characteristic curveof radiographic film
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 47: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/47.jpg)
Pixels
Digital Images ndash Bit Depth
bull Pixel values can be any bit depth (values from 0 to 1023)
bull Bit depth = or gray shades available for image display
bull Image contrast can be manipulated to stretched or contracted to alter the displayed contrast
bull Typically use ldquowindow widthrdquo and ldquowindow levelrdquo to alter displayed contrast and brightness
Digital - Grayscale
Bit depth Number of gray shades
available for display 8 bit 256 10 bit 1024 12 bit 4096 4 bit 16384
Display Bit Depth1 bit 6 bit 8 bit
2 shades 64 shades 256 shades
Computed Radiography As the plate is scanned ldquoreadrdquo data is collected
at a specific frequency = Sampling frequency
Spatial resolution determined by sampling frequency
With some systems the smaller IRrsquos have higher sampling frequencies amp more pixels per mm = more spatial resolution
Signal Loss (reducing image quality) Signal-to-Noise Ratio
Principle source of noise on the image is scatter radiation
Scattering of emitted light off screen
The efficiency of the photomultiplier tubes (PMTs) and photodiodes (PDs)
Improving Signal-to-Noise Ratio
Optical filter is used to prevent the longer-wavelength laser light affecting the image formation
Increasing exposure to IR Newer CR systems are better at reducing noise at lower exposure levels
Technique Selections
What are some factors that technologist must take into consideration when selecting a technique
What regulates that technologists to select appropriate techniques in FS CR amp DR
Screen Film
Self regulating system The receptor speed and film HampD curve defined
the proper exposure Achieving optimal OD guaranteed appropriate
exposure to the patient Over exposed = dark image Correct exposure = correct OD Under exposed = light image
Characteristic curveof radiographic film
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 48: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/48.jpg)
Digital Images ndash Bit Depth
bull Pixel values can be any bit depth (values from 0 to 1023)
bull Bit depth = or gray shades available for image display
bull Image contrast can be manipulated to stretched or contracted to alter the displayed contrast
bull Typically use ldquowindow widthrdquo and ldquowindow levelrdquo to alter displayed contrast and brightness
Digital - Grayscale
Bit depth Number of gray shades
available for display 8 bit 256 10 bit 1024 12 bit 4096 4 bit 16384
Display Bit Depth1 bit 6 bit 8 bit
2 shades 64 shades 256 shades
Computed Radiography As the plate is scanned ldquoreadrdquo data is collected
at a specific frequency = Sampling frequency
Spatial resolution determined by sampling frequency
With some systems the smaller IRrsquos have higher sampling frequencies amp more pixels per mm = more spatial resolution
Signal Loss (reducing image quality) Signal-to-Noise Ratio
Principle source of noise on the image is scatter radiation
Scattering of emitted light off screen
The efficiency of the photomultiplier tubes (PMTs) and photodiodes (PDs)
Improving Signal-to-Noise Ratio
Optical filter is used to prevent the longer-wavelength laser light affecting the image formation
Increasing exposure to IR Newer CR systems are better at reducing noise at lower exposure levels
Technique Selections
What are some factors that technologist must take into consideration when selecting a technique
What regulates that technologists to select appropriate techniques in FS CR amp DR
Screen Film
Self regulating system The receptor speed and film HampD curve defined
the proper exposure Achieving optimal OD guaranteed appropriate
exposure to the patient Over exposed = dark image Correct exposure = correct OD Under exposed = light image
Characteristic curveof radiographic film
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 49: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/49.jpg)
Digital - Grayscale
Bit depth Number of gray shades
available for display 8 bit 256 10 bit 1024 12 bit 4096 4 bit 16384
Display Bit Depth1 bit 6 bit 8 bit
2 shades 64 shades 256 shades
Computed Radiography As the plate is scanned ldquoreadrdquo data is collected
at a specific frequency = Sampling frequency
Spatial resolution determined by sampling frequency
With some systems the smaller IRrsquos have higher sampling frequencies amp more pixels per mm = more spatial resolution
Signal Loss (reducing image quality) Signal-to-Noise Ratio
Principle source of noise on the image is scatter radiation
Scattering of emitted light off screen
The efficiency of the photomultiplier tubes (PMTs) and photodiodes (PDs)
Improving Signal-to-Noise Ratio
Optical filter is used to prevent the longer-wavelength laser light affecting the image formation
Increasing exposure to IR Newer CR systems are better at reducing noise at lower exposure levels
Technique Selections
What are some factors that technologist must take into consideration when selecting a technique
What regulates that technologists to select appropriate techniques in FS CR amp DR
Screen Film
Self regulating system The receptor speed and film HampD curve defined
the proper exposure Achieving optimal OD guaranteed appropriate
exposure to the patient Over exposed = dark image Correct exposure = correct OD Under exposed = light image
Characteristic curveof radiographic film
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 50: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/50.jpg)
Display Bit Depth1 bit 6 bit 8 bit
2 shades 64 shades 256 shades
Computed Radiography As the plate is scanned ldquoreadrdquo data is collected
at a specific frequency = Sampling frequency
Spatial resolution determined by sampling frequency
With some systems the smaller IRrsquos have higher sampling frequencies amp more pixels per mm = more spatial resolution
Signal Loss (reducing image quality) Signal-to-Noise Ratio
Principle source of noise on the image is scatter radiation
Scattering of emitted light off screen
The efficiency of the photomultiplier tubes (PMTs) and photodiodes (PDs)
Improving Signal-to-Noise Ratio
Optical filter is used to prevent the longer-wavelength laser light affecting the image formation
Increasing exposure to IR Newer CR systems are better at reducing noise at lower exposure levels
Technique Selections
What are some factors that technologist must take into consideration when selecting a technique
What regulates that technologists to select appropriate techniques in FS CR amp DR
Screen Film
Self regulating system The receptor speed and film HampD curve defined
the proper exposure Achieving optimal OD guaranteed appropriate
exposure to the patient Over exposed = dark image Correct exposure = correct OD Under exposed = light image
Characteristic curveof radiographic film
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 51: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/51.jpg)
Computed Radiography As the plate is scanned ldquoreadrdquo data is collected
at a specific frequency = Sampling frequency
Spatial resolution determined by sampling frequency
With some systems the smaller IRrsquos have higher sampling frequencies amp more pixels per mm = more spatial resolution
Signal Loss (reducing image quality) Signal-to-Noise Ratio
Principle source of noise on the image is scatter radiation
Scattering of emitted light off screen
The efficiency of the photomultiplier tubes (PMTs) and photodiodes (PDs)
Improving Signal-to-Noise Ratio
Optical filter is used to prevent the longer-wavelength laser light affecting the image formation
Increasing exposure to IR Newer CR systems are better at reducing noise at lower exposure levels
Technique Selections
What are some factors that technologist must take into consideration when selecting a technique
What regulates that technologists to select appropriate techniques in FS CR amp DR
Screen Film
Self regulating system The receptor speed and film HampD curve defined
the proper exposure Achieving optimal OD guaranteed appropriate
exposure to the patient Over exposed = dark image Correct exposure = correct OD Under exposed = light image
Characteristic curveof radiographic film
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 52: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/52.jpg)
Signal Loss (reducing image quality) Signal-to-Noise Ratio
Principle source of noise on the image is scatter radiation
Scattering of emitted light off screen
The efficiency of the photomultiplier tubes (PMTs) and photodiodes (PDs)
Improving Signal-to-Noise Ratio
Optical filter is used to prevent the longer-wavelength laser light affecting the image formation
Increasing exposure to IR Newer CR systems are better at reducing noise at lower exposure levels
Technique Selections
What are some factors that technologist must take into consideration when selecting a technique
What regulates that technologists to select appropriate techniques in FS CR amp DR
Screen Film
Self regulating system The receptor speed and film HampD curve defined
the proper exposure Achieving optimal OD guaranteed appropriate
exposure to the patient Over exposed = dark image Correct exposure = correct OD Under exposed = light image
Characteristic curveof radiographic film
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 53: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/53.jpg)
Improving Signal-to-Noise Ratio
Optical filter is used to prevent the longer-wavelength laser light affecting the image formation
Increasing exposure to IR Newer CR systems are better at reducing noise at lower exposure levels
Technique Selections
What are some factors that technologist must take into consideration when selecting a technique
What regulates that technologists to select appropriate techniques in FS CR amp DR
Screen Film
Self regulating system The receptor speed and film HampD curve defined
the proper exposure Achieving optimal OD guaranteed appropriate
exposure to the patient Over exposed = dark image Correct exposure = correct OD Under exposed = light image
Characteristic curveof radiographic film
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 54: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/54.jpg)
Technique Selections
What are some factors that technologist must take into consideration when selecting a technique
What regulates that technologists to select appropriate techniques in FS CR amp DR
Screen Film
Self regulating system The receptor speed and film HampD curve defined
the proper exposure Achieving optimal OD guaranteed appropriate
exposure to the patient Over exposed = dark image Correct exposure = correct OD Under exposed = light image
Characteristic curveof radiographic film
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 55: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/55.jpg)
Screen Film
Self regulating system The receptor speed and film HampD curve defined
the proper exposure Achieving optimal OD guaranteed appropriate
exposure to the patient Over exposed = dark image Correct exposure = correct OD Under exposed = light image
Characteristic curveof radiographic film
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 56: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/56.jpg)
Characteristic curveof radiographic film
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 57: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/57.jpg)
Characteristic Curve
Sometimes called the HampD curve for Hurter and Driffield who first described the relationship
Describes the relationship between OD and exposure
Exposure changes near the toe or shoulder result in very little OD changes
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 58: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/58.jpg)
Screen Film Imaging = self regulating
2 mAsUnder exposed
6 mAsCorrect exposure
24 mAsOver exposed
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 59: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/59.jpg)
CR imaging results in 10000 shades of gray
Fixed kVp exposures
mAs = 05S = 357
mAs = 10 S = 175
mAs = 20S = 86
mAs = 50S = 35
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 60: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/60.jpg)
SF fundamental principle
Keep receptor exposure constant for given receptor response
The receptor exposure level (mR) depends on
Receptor ldquospeedrdquo 100 speed ~ 2 mR (to IR for appropriate OD)
200 speed ~1 mR 400 speed ~ 05 mR
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 61: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/61.jpg)
Speed Class
For CR imaging the speed is determined by the image quality required by the Radiologists or programmed by the service engineer Dependent on exposure to the PSP plate 200 RS = highest quality images Increasing RS will reduce contrast resolution and patient dose
S numbers Index numbers Sensitivity numbers Exposure index
Each imaging system is unique
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 62: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/62.jpg)
Dose Implications
Images nearly always look better at
higher exposures
FS system on average used a 400 RS combinationCR looks best at 200 RS If you were a manufacture how would you set up
your system for image quality vs ALARA
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 63: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/63.jpg)
55 15 30
100 200 500
80 KVP
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 64: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/64.jpg)
Dose Implications Huge dynamic range means nearly impossible to
overexpose
Then the COMPUTER corrects majority of exposure errors
Therefore almost ANY technique can be used on the patient ndash
The computer will fix it
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 65: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/65.jpg)
POST PROCESSING
Part Selection
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 66: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/66.jpg)
Workstation Menu
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 67: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/67.jpg)
ALGORITHM ndash a set of mathematical values used to solve a problem or find an average
HISTOGRAM ndash a bar graph depicting the density distribution (in numerical values) of the imaging plate
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 68: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/68.jpg)
Wrong Algorithm
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 69: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/69.jpg)
Histogram showing pixel values in an image The pixel values in gray are on the horizontal with the total number for each on the vertical
DarkerLighter
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 70: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/70.jpg)
Histogram Analysis
A histogram is a plot of gray scale value vs the frequency of occurrence
pixels of the gray value in the image A graph that displays signal value x-axis related to amount of exposure y-axis displays number of pixels for each exposure Series of peaks and valleys Pattern varies for each body part
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 71: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/71.jpg)
Statistical plots of the
frequency of occurrence of
each pixels value
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 72: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/72.jpg)
Initial Image Processing
Automated exposure field edge detection
Eliminates signals outside collimation margins
If margin not detected extraneous data included in the histogram
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 73: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/73.jpg)
EDR
Exposure Data Recognition When laser scans it is looking for area of
plate that has exposure Some read from center out and look for
two sides of collimation Works best when image centered
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 74: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/74.jpg)
Exposure Indicators
Imaging plates get a signal from the exposure they receive
The value of the signal is calculated from the region identified as the anatomy of interest
The signal for the plate is an average of all signals given to the plate
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 75: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/75.jpg)
Exposure Values
Each system has range of values for appropriate exposure for part
The range used by vendor is very broad Each facility should develop its own
exposure range taking into accountRadiologist preferenceALARA
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 76: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/76.jpg)
S numbers Index numbers Sensitivity numbers Exposure index
The total signal is not a measure of the dose to the patient but indicates how much radiation was absorbed by the plate
A 1 mR exposure will giveFuji S 200KodakCarestream EI 2000Agfa 200 speed lgm reference value for site
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 77: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/77.jpg)
EXPOSURE VALUES
Exposure indicatorPlates sensitive to 01 mR ndash 100 mR ldquoSrdquo number for Fuji
S number inverse to exposureS=2 (100 mR) S=200 (1 mR)
CarestreamKodak uses exposure index ndash direct relationship2000 (1 mR) 3000 (10 mR)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 78: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/78.jpg)
Using Exposure Numbers
Fuji if appropriate is 200 thenAt 400 too light double mAs for 200At 100 too dark half mAs for 200
Kodak if appropriate is 1800At 1500 too light double mAs for 1800At 2100 to dark half mAs for 1800
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 79: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/79.jpg)
Exposure Numbers
The exposure numbers can only be used if all other parameters are correctCentering to plateCollimation
Position over AEC look at mAs readout to determine if poor positioning caused light or dark image
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 80: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/80.jpg)
S 12361 lat CXRS 8357
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 81: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/81.jpg)
Same technique different centering and collimation
S 592S 664
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 82: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/82.jpg)
2 on 24 X 301048697Same technique1048697Rescaling error
10486972 on 24 X 301048697Technique adjusted
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 83: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/83.jpg)
Histogram Analysis Collimation is very important
If plate reader cannot find collimated edges then all the exposure on plate will be included in the histogram
Histogram from plate is compared to body part histogram stored in computer
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 84: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/84.jpg)
Characteristic curve amp histogram
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 85: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/85.jpg)
Histogram with HampD curve
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 86: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/86.jpg)
Underexposed
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 87: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/87.jpg)
Overexposed
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 88: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/88.jpg)
Just right
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 89: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/89.jpg)
Changes to Histogram
Hip prosthesis
Line caused from dirt collected in a CR Reader
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 90: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/90.jpg)
Higher kVp
bull Smaller signal difference
bull Narrower data range
bull Photons to IR
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 91: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/91.jpg)
Lower kVp
bull Larger signal difference
bull Wider data range
bull More photons will be absorbed
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 92: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/92.jpg)
kVp vs Data Width
bull Very difficult concept for radiographer
bull Focused on exposure vs appearance
bull High kVp = longer scale = wider
bull Low kVp = shorter scale = narrower
bull Change focus to underlying physics
bull High kVp = less differential attenuation
bull Smaller signal difference
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 93: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/93.jpg)
LUT Look Up Table (LUT) Each anatomic area has a LUT or
Algorithm Used to adjust contrast and density Other terms that may be used for this
Contrast rescalingContrast processingGradation processingTone scaling
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 94: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/94.jpg)
LUT
The image data from the histogram is rescaled for application of the LUT
The LUT maps the adjusted data through a ldquoSrdquo curve that is similar to an H amp D curve
The result is an image that has the correct contrast and brightness (density)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 95: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/95.jpg)
Automatic rescaling
Mapping grayscale to ldquopixel values of interestrdquo to achieve specific display levels
Critical elementsPeaksTroughsWidthLocates VOI (values of interest)Exposure index determination
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 96: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/96.jpg)
LUT
1 is unprocessed 2 algorithm finds anatomy 3 finished
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 97: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/97.jpg)
Myths for CR 1 amp 2
1 mAs ndash myth digital is mAs driven Truth
2 kVp ndash myth digital is kVp driven Truth
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 98: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/98.jpg)
Contrast
What determines contrast Which factors have more impact on contrast than
kVp for all systems Anatomical structure Contrast media Grid utilization Grid vs non-grid Grid efficiency Processing algorithm
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 99: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/99.jpg)
TECHNIQUE CONISDERATIONS
kVp energy dependant
Now COMPUTER controls CONTRAST
Higher kVp to stimulate electron trapskVp range for CR 45 - 120
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 100: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/100.jpg)
Using Higher kVp with Digital
There is a limit If higher kVp is used to limit doseRemember basic physics
Higher kVp ndash more transmission Lower kVp ndash more photoelectric Too low mAs can cause quantum mottle
regardless of kVp used
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 101: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/101.jpg)
kVp Selection
Anatomical contrast Inherent Δ attenuation due to structure Grid utilization Yes No Efficiency
Ratio frequency lead content Contrast improvement Default processing algorithm
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 102: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/102.jpg)
kVp Selection
Determined by anatomy and grid Adults 1048707 Optimal range 60 ndash 120 1048707 Pediatrics lt 100 lbs Optimal range 50 -
90 May use higher kVp than with SF Helps limit dose increase Narrows acquired data range
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 103: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/103.jpg)
kVp ranges for CR
Infant extremities 50 - 60 kVp
Adult extremities 65 - 75 kVp
Bucky extremities 75 ndash 90 kV
AP spine 85 - 95 kVp
Lateral spine 85 ndash 100 kVp
Chest 110 ndash 130 kVp Skull 80 ndash 90 kVp
Only 1 kVp is not reccomended
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 104: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/104.jpg)
Another set of suggested kVp ranges Distal Extremities =
65 ndash 75 Ped extremities = 50
- 65 KUB = 80 - 85 IVU = 70 ndash 80 BE = 110 -120
Grid extremities = 85 - 90
L-spinePelvis = 85 ndash 90 Chest grid = 110 ndash 130 Ped chest NG 70 ndash 80 Ribs = 80 ndash 90 T-spine = 90 ndash 100
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 105: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/105.jpg)
Collimation
Proper collimation is the best way to enhance your CR image Why
What is shuttering
Is it the same as collimating
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 106: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/106.jpg)
Myths for CR 3
Collimation ndash myth you cannot collimateTruth
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 107: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/107.jpg)
Shuttering
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 108: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/108.jpg)
If radiologist objectApply back border
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 109: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/109.jpg)
Collimation
Collimation Less water irradiated Less scatter produced Improves contrast Reduces effective dose Reduces automatic rescaling errors
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 110: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/110.jpg)
Exposure Field RecognitionIf the exposure field is not recognized the entire plate is used in image construction
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 111: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/111.jpg)
Myths for CR 4
Grid ndash myth cannot use grids and donrsquot need them Truth
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 112: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/112.jpg)
Grid vs Non-grid
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 113: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/113.jpg)
Myths for CR 5
5 SID ndash myth magnification doesnrsquot occur with digital so SID is unimportant Truth
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 114: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/114.jpg)
Myths for CR 6
Speed class ndash myth it is a 200 speed class you need to double your mAs and increase your kVp by 10 Truth
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 115: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/115.jpg)
Myth for CR 7 amp 8
7 Fog ndash myth digital systems canrsquot be fogged by scatter or background radiation Truth
Myth fluorescent lights fog PSP plates Truth
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 116: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/116.jpg)
ADVANTAGE OF CRDR vs FS
Rapid storage retrieval of images NO LOST FILMS PACS (storage management) Teleradiology - long distance transmission
of image information Economic advantage - at least in the long
run
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 117: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/117.jpg)
ADVANTAGE OF CRDR
Can optimize image quality by manipulating digital data to improve visualization of anatomy and pathology AFTER EXPOSURE TO PATIENT
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 118: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/118.jpg)
Image Preprocessing
Data recognition is very important
Two on one imaging Can it be done Is it good practice
Carter pg 87
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 119: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/119.jpg)
Improves Exam Times Improves Exam Times
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 120: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/120.jpg)
High resolution with digital imaging
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 121: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/121.jpg)
NEW IMAGEbull towel that was used
to help in positioning a child
bull CR is MORE sensitive to
bull ARTIFACTS
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-
![Page 122: Computed Radiography. Objectives Historical perspectives of computerized imaging S/F vs CR vs DDR imaging Basics of CR image capture CR imaging equipment](https://reader035.vdocuments.mx/reader035/viewer/2022081503/56649ebd5503460f94bc6302/html5/thumbnails/122.jpg)
Questions
- Digital Imaging
- Development of Digital Imaging
- First-generation CT unit dedicated head scanner (Photograph taken at Roentgen Museum Lennep Germany)
- Methods to Digitize an Image
- Slide 11
- Conventional radiography latent image formation
- CR latent image formation
- Slide 19
- Slide 24
- Slide 38
- Slide 41
- Basics of Digital Images
- Matrix = each cell corresponds to a specific location on the image
- Pixel
- Slide 49
- Digital Images ndash Bit Depth
- Display Bit Depth 1 bit 6 bit 8 bit
- Screen Film Imaging = self regulating
- CR imaging results in 10000 shades of gray Fixed kVp exposures
- Slide 65
- Slide 66
- Workstation Menu
- Wrong Algorithm
- Slide 72
- Slide 83
- Same technique different centering and collimation
- Slide 85
- Characteristic curve amp histogram
- Histogram with HampD curve
- Underexposed
- Overexposed
- Just right
- Changes to Histogram
- Higher kVp
- Lower kVp
- kVp vs Data Width
- Slide 99
- Slide 104
- Shuttering
- If radiologist object Apply back border
- Slide 114
- Exposure Field Recognition If the exposure field is not recognized the entire plate is used in image construction
- Slide 116
- Slide 117
- Slide 118
- Slide 119
- Slide 120
- Grid vs Non-grid
- NEW IMAGE
-