alveolar gas equation
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Alveolar Gas Equation. Oxygenation www.mecriticalcare.net. The Key to Blood Gas Interpretation: Four Equations, Three Physiologic Processes. Equation Physiologic Process 1) PaCO2 equation Alveolar ventilation 2) Alveolar gas equation Oxygenation - PowerPoint PPT PresentationTRANSCRIPT
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Alveolar Gas Equation
Oxygenationwww.mecriticalcare.net
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The Key to Blood Gas Interpretation:Four Equations, Three Physiologic Processes
Equation Physiologic Process1) PaCO2 equation Alveolar ventilation2) Alveolar gas equation Oxygenation3) Oxygen content equation Oxygenation4) Henderson-Hasselbalch equation Acid-base balance
These four equations, crucial to understanding and interpreting arterial blood gas data.
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Normal Arterial Blood Gas Values*
pH 7.35 - 7.45PaCO2 35 - 45 mm HgPaO2 70 - 100 mm Hg **SaO2 93 - 98%HCO3¯ 22 - 26 mEq/L%MetHb < 2.0%%COHb < 3.0%Base excess -2.0 to 2.0 mEq/LCaO2 16 - 22 ml O2/dl
• * At sea level, breathing ambient air• ** Age-dependent
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Oxygenation and Ventilation
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Oxygen Saturation Monitoring by Pulse Oximetry
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O2-Hg Dissociation CurveH
b S
atur
atio
n)%
)
PaO2 (mm Hg)
90%
60 600
100%
90
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Oxygen Saturation Monitoring by Pulse Oximetry
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Patient Environments• Ambient Light
– Any external light exposure to capillary bed where sampling is occurring may result in an erroneous reading
• Excessive Motion– Always compare the palpable pulse rate with the pulse rate
indicated on the pulse oximetry• Fingernail polish and false nails
– Most commonly use nails and fingernail polish will not affect pulse oximetry accuracy
– Some shades of blue, black and green may affect accuracy )remove with acetone pad)
• Skin pigmentation– Apply sensor to the fingertips of darkly pigmented patients
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Conditions Affecting Accuracy• Patient conditions
– Carboxyhemoglobin• Erroneously high reading may present
– Methaemoglobin– Anemia
• Values as low as 5 g/dl may result in 100% SpO2– Hypovolemia/Hypotension:
• May not have adequate perfusion to be detected by oximetry
– Hypothermia:• peripheral vasoconstriction may prevent oximetry detection
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Nasal Cannula: Variable Flow
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Simple Face Mask: Variable Flow
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Venturi Mask: Fixed Flow
blue = 24%; yellow = 28%; white = 31%; green = 35%; pink = 40%; orange = 50%
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Venturi Effect
The pressure at "1" is higher than at "2" because the fluid speed at "1" is lower than at "2."
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Venturi Effect
A flow of air through a venturi meter, showing the columns connected in a U-shape )a manometer) and partially filled
with water. The meter is "read" as a differential pressure head in cm or inches of water.
4-15 L/min35-45 L/min
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Variable Performance Device: Nonrebreather Mask
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100
90
80
70
60
50
40
30
20
10
05 15 25 35 45 55 65 75 85
5 L.min-1
10 L.min-1
20 L.min-1
30 L.min-1
Frac
tion
al in
spir
ed o
xyge
n co
ncen
trat
ion
%
Peak inspiratory flow (liters/minute)
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Continuous Airway Pressure: CPAP
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Alveolar-arterial Oxygen Gradient
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PAO2= (Patm-PH2O) FiO2- PACO2/0.8 760 47 0.21 40
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Alveolar Gas Equation PAO2 = PIO2 - 1.2 (PaCO2)*
PAO2 = FIO2 (PB – 47 mm Hg) - 1.2 (PaCO2)
A-a Gradient= PAO2- PaO2 =5-25 mm Hg
PAO2 is the average alveolar PO2
PIO2 is the partial pressure of inspired oxygen in the tracheaFIO2 is fraction of inspired oxygen PB is the barometric pressure. 47 mm Hg is the water vapor pressure at normal body temperature* Note: This is the “abbreviated version” of the AG equation, suitable for most clinical purposes. In the longer version, the multiplication factor “1.2” declines with increasing FIO2, reaching zero when 100% oxygen is inhaled. In these exercises “1.2” is dropped when FIO2 is above 60%.
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Hypoxemia Due to Hypercapnia
↓PAO2 = FIO2 (PB – 47 mm Hg) - 1.2 (↑PaCO2)
Hypercapneic Respiratory Failure
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Hypoxemia Due to Decreased FiO2
↓PAO2 = ↓FIO2 (PB – 47 mm Hg) - 1.2 (PaCO2)
Suffocation
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High Altitude Hypoxemia
↓PAO2 = FIO2 (↓PB – 47 mm Hg) - 1.2 (PaCO2)
Mountain climbing
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Alveolar Gas Equation: Test Your Understanding
What is the expected PaO2 in a normal lung patient at sea level in the following circumstances? )Barometric pressure = 760 mm Hg)
A. FIO2 = 1.00, PaCO2 = 30 mm HgPAO2 = 1.00 (713) - 30 = 683 mm Hg, PaO2= 673
B. FIO2 = .21, PaCO2 = 50 mm HgPAO2 = .21 (713) - 1.2 (50) = 90 mm Hg, PaO2 = 80
C. FIO2 = .40, PaCO2 = 30 mm HgPAO2 = .40 (713) - 1.2 (30) = 249 mm Hg, PaO2 = 239
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Alveolar Gas Equation: Test Your Understanding
What is the PAO2 on the summit of Mt. Everest in the following circumstances? )Barometric pressure = 253 mm Hg)
A. FIO2 = .21, PaCO2 = 40 mm HgB. FIO2 = 1.00, PaCO2 = 40 mm HgC. FIO2 = .21, PaCO2 = 10 mm Hg
A. PAO2 = .21 (253 - 47) - 1.2 (40) = - 5 mm HgB. PAO2 = 1.00 (253 - 47) - 40 = 166 mm HgC. PAO2 = .21 (253 - 47) - 1.2 (10) = 31 mm Hg
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Alveolar Arterial O2 Gradient
EpitheliumEndothelium
Po2 Po2
Alveolar Gas Capillary Blood
initial Initial
Thickness
A-a Gradient
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Alveolar Arterial O2 Gradient
EpitheliumEndothelium
Alveolar Gas Capillary BloodThickness
FIO2= 21% PAO2= 100 PaO2= 95
5FIO2= 50% PAO2= 331 PaO2= 326
FIO2= 100% PAO2= 663 PaO2= 657
O2 Sat= 99%
O2 Sat= 100%
O2 Sat= 100%
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Alveolar Arterial O2 Gradient
EpitheliumEndothelium
Alveolar Gas Capillary BloodThickness
200FIO2= 50% PAO2= 331 PaO2= 131
FIO2= 100% PAO2= 663 PaO2= 463
O2 Sat= 100%
O2 Sat= 100%
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Alveolar-arterial Oxygen Gradient
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Physiologic Causes of Low PaO2
NON-RESPIRATORY P(A-a)O2Cardiac right-to-left shunt Increased
Decreased PIO2 Normal
Low mixed venous oxygen content* Increased
* Unlikely to be clinically significant unless there is right-to-left shunting or ventilation-perfusion imbalance
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Physiologic Causes of Low PaO2
RESPIRATORY P(A-a)O2Pulmonary right-to-left shunt Increased
Ventilation-perfusion imbalance Increased
Diffusion barrier Increased
Hypoventilation )increased PaCO2) Normal
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A 44-year-old woman with: PaCO2 75 mm Hg, PaO2 95 mm Hg, FIO2 0.28
PAO2 = FIO2 (PB – 47 mm Hg) - 1.2 (PaCO2)
PAO2 = .28 )713) - 1.2 )75) PAO2= 200 - 90 =110 mm HgP(A-a)O2 = 110 - 95 = 15 mm Hg
Despite severe hypoventilation, there is no evidence here for lung disease. Hypercapnia is most likely a result of disease elsewhere in the respiratory system, either the central nervous system or chest bellows
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A young, anxious man with: PaO2 120 mm Hg, PaCO2 15 mm Hg, FIO2 0.21
PAO2 = FIO2 (PB – 47 mm Hg) - 1.2 (PaCO2)
PAO2 = .21 )713) - 1.2 )15) PAO2= 150 - 18 =132 mm HgP(A-a)O2 = 132 - 120 = 12 mm Hg
Hyperventilation can easily raise PaO2 above 100 mm Hg when the lungs are normal, as in this case
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A woman in the ICU with: PaO2 350 mm Hg, PaCO2 40 mm Hg, FIO2 0.80
PAO2 = FIO2 (PB – 47 mm Hg) - 1.2 (PaCO2)
PAO2 = .80 )713) - )40) PAO2= 570 - 40 = 530 mm HgP(A-a)O2 = 530 - 350 = 180 mm Hg
Note that the factor 1.2 is dropped since FIO2 is above 60%P)A-a)O2 is increased. Despite a very high PaO2, the lungs are not transferring
oxygen normally.
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A man with: PaO2 80 mm Hg, PaCO2 72 mm Hg, FIO2 0.21
PAO2 = FIO2 (PB – 47 mm Hg) - 1.2 (PaCO2)
PAO2 = .21 )713) – 1.2)72) PAO2= 150 - 86 = 64 mm HgP(A-a)O2 = 64 - 72 = -16 mm Hg
A negative P)A-a)O2 is incompatible with life )unless it is a transient unsteady state, such as sudden fall in FIO2 -- not the case here). In this example, negative P)A-a)O2 can be explained by any of the following: incorrect FIO2, incorrect blood gas measurement, or a reporting or transcription error.
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40 Thank You