EUROPEAN CONGRESS ON ANTI-AGING AND EUROPEAN CONGRESS ON ANTI-AGING AND AESTHETIC MEDICINEAESTHETIC MEDICINE
15-17 OCTOBER 209915-17 OCTOBER 2099
MAINZ - FRANKFURT, GERMANYMAINZ - FRANKFURT, GERMANY
Successful healing and anti - aging withSuccessful healing and anti - aging with
specific low frequencyspecific low frequency
Electro Magnetic fields.Electro Magnetic fields.
Dr. med. Wolf-Dieter Kessler Dr. med. Wolf-Dieter Kessler
SPECIFIC PHOTONS FOR ANTI-AGINGSPECIFIC PHOTONS FOR ANTI-AGING
Each tissue is very specificEach tissue is very specific
Has a specific Larmor spinHas a specific Larmor spin
Can be contrasted in the MRI Can be contrasted in the MRI
Numerous health disorders can be successfully Numerous health disorders can be successfully improved by specific pulsing em fieldsimproved by specific pulsing em fields
TinnitusTinnitusBrain disordersBrain disordersAny infections/parasitesAny infections/parasitesAutismAutismAllergiesAllergiesBladderBladderProstateProstateEye problemsEye problemsCancer (much better tolerance of Cancer (much better tolerance of chemotherapy)chemotherapy)Pre-operationPre-operationPost-operationPost-operationBack problemsBack problemsGoiterGoiterOsteporosisOsteporosisBone healing /non jointed bone fracturesBone healing /non jointed bone fractures
etcetc
Guidance for the therapistGuidance for the therapist
Where to go (Main Focus)Where to go (Main Focus)
How to treat (Frequency Field)How to treat (Frequency Field)
What to treat (Microorganisms)What to treat (Microorganisms)
Field Intensity, Field StrengthField Intensity, Field Strength
50 – 500 Gaus50 – 500 Gaus
5 – 50 milli Tesla5 – 50 milli Tesla
Field intensities used in medicine:Field intensities used in medicine:
MRI 1.5 – 4.5 TeslaMRI 1.5 – 4.5 Tesla
Shock therapy in psychiatry 2 TeslaShock therapy in psychiatry 2 Tesla
Spectroscopy and SpecificitySpectroscopy and SpecificityLight travels in packagesLight travels in packages
Gilbert Newton Lewis, 1875 -1946Gilbert Newton Lewis, 1875 -1946
named light quanta “photons”named light quanta “photons”
Specific pulsing em fields produce specificSpecific pulsing em fields produce specific
photons in the aging tissue through nuclear photons in the aging tissue through nuclear
magnetic resonancemagnetic resonance
Why specific?Why specific?
Hydrogens of different tissues haveHydrogens of different tissues have
different spins different spins
ORGANS ARE LIKE BELLSORGANS ARE LIKE BELLS
Dielectric constant (kappa)Dielectric constant (kappa)
Biophoton Emisson from LeafBiophoton Emisson from LeafProfessor Fritz-Alfred PoppProfessor Fritz-Alfred Popp
Tissue in pain is emitting less photons. Dead cells Tissue in pain is emitting less photons. Dead cells do not emit photonsdo not emit photons
What happens if the number of cellular photons What happens if the number of cellular photons reaches a critical low number?reaches a critical low number?
Myungshik Kim and Marco BelliniIstituto Nazionale di Ottica Applicata
Florence, ItalyEuropean Laboratory for Non-linear Spectroscopy
Subtracting one photon from the light field
Specific pulsing em fieldsSpecific pulsing em fields
cause a dramatic pain relief in patients with severecause a dramatic pain relief in patients with severe
osteoporosis. People become motile again .osteoporosis. People become motile again .
How does this work?How does this work?
Spinning hydrogen atoms of our tissues and Spinning hydrogen atoms of our tissues and focusfocus
University of Boulder, ColoradoUniversity of Boulder, Colorado
Photon emission and focusPhoton emission and focusUniversity of Boulder ColoradoUniversity of Boulder Colorado
The energy to put life in order comes from The energy to put life in order comes from photons. It is the photon pump which condenses photons. It is the photon pump which condenses
photons to laser like light. The process is based on photons to laser like light. The process is based on resonance. Like spectra are attracted resonance. Like spectra are attracted
by like spectra.Like photons are attracted by like by like spectra.Like photons are attracted by like photons. photons.
Erwin SchrödingerErwin SchrödingerNobel Prize in Physics 1933 Nobel Prize in Physics 1933
In physics, resonance is the tendency of a systemIn physics, resonance is the tendency of a system to oscillate at maximum amplitude at certain to oscillate at maximum amplitude at certain frequenciesfrequencies
Photons are attracted to any protein, DNA site, Photons are attracted to any protein, DNA site, molecule, electron if their spectral waves match molecule, electron if their spectral waves match that one of the protein or electron. Matching that one of the protein or electron. Matching means means resonance takes place resonance takes place and sublte and sublte energies would build up enormous energies energies would build up enormous energies needed to dynamise aging or ailing tissues or to needed to dynamise aging or ailing tissues or to build up food. build up food.
Left: Energie level diagram of the ground and excited states of Left: Energie level diagram of the ground and excited states of chlorophyll achlorophyll a and and ββ - -carotene.carotene. Right: Right: Two-Photon excitation spectroscopy (red line with red Two-Photon excitation spectroscopy (red line with red dots) enables the dots) enables the
measurement of spectra of the carotenoid dark state within intact pigment-protein measurement of spectra of the carotenoid dark state within intact pigment-protein complexes. The example shows spectra of Photosystem I:complexes. The example shows spectra of Photosystem I:
Absorption spectrum (green line), Fluorescence spectrum (black line) and the Absorption spectrum (green line), Fluorescence spectrum (black line) and the already mentioned two-photon excitation spectrum (red line). For details see M. already mentioned two-photon excitation spectrum (red line). For details see M.
Hilbert, A. Wehling, E. Schlodder and P. J. WallaHilbert, A. Wehling, E. Schlodder and P. J. Walla
Steroid receptors are zinc finger proteinsSteroid receptors are zinc finger proteins
Photolyases are DNA repair enzymes that repair Photolyases are DNA repair enzymes that repair damage caused by exposure to damage caused by exposure to ultravioletultraviolet light. light. This enzyme mechanism requires This enzyme mechanism requires visible lightvisible light, ,
preferentially from the violet/blue end of the preferentially from the violet/blue end of the spectrum, and is known as spectrum, and is known as photoreactivationphotoreactivation..
Fundamental chemical lawFundamental chemical law
In order to activate the receptor protein, it In order to activate the receptor protein, it
must be excited must be excited
În the living matrix this is done by Photon În the living matrix this is done by Photon
Resonance with the proteinResonance with the protein
The idea that energy within a living system may beThe idea that energy within a living system may betransported within semiconductive bands of transported within semiconductive bands of
proteins was suggested by SZENT-GYÖRGYI in proteins was suggested by SZENT-GYÖRGYI in 1941. 1941.
Living cells are emitting lightLiving cells are emitting light
Living cells absorb lightLiving cells absorb light
Professor Fritz Popp, GermanyProfessor Fritz Popp, Germany
Very weak electromagnetic fields at the Very weak electromagnetic fields at the appropriate frequencies can be as effective, or appropriate frequencies can be as effective, or even better, than other approaches for reducing even better, than other approaches for reducing inflammation, counteracting diseases, and inflammation, counteracting diseases, and enhancing longevity. The mechanism involves enhancing longevity. The mechanism involves resonance, the process by which a field of a resonance, the process by which a field of a particular frequency or wavelength can transfer particular frequency or wavelength can transfer vibrational energy to an object.vibrational energy to an object.
Clinical applications of electromagnetic Clinical applications of electromagnetic resonance have the advantage that they can act resonance have the advantage that they can act at a distance using tiny fields that excite or at a distance using tiny fields that excite or energize natural processes taking place deep energize natural processes taking place deep within the body.within the body.
James Oschman, PhDJames Oschman, PhD
Specific Pulsing Electromagnetic FieldsSpecific Pulsing Electromagnetic Fields
(SPEMF) adjust treatment to the individual (SPEMF) adjust treatment to the individual patient and the process can take place in the patient and the process can take place in the Main Focus Area Main Focus Area
The question is:The question is:
Which mechanism produces photons which Which mechanism produces photons which
match ailing tssue structures?match ailing tssue structures?
You select the resonating pemf by a simple pulse You select the resonating pemf by a simple pulse reaction.reaction.
Then nuclear magnetic resonance takes place Then nuclear magnetic resonance takes place
and activates photons which match the spectra and activates photons which match the spectra
of the ailing tissue of the ailing tissue
SPECIFIC EM FIELDSSPECIFIC EM FIELDS
Find the ailing tissuesFind the ailing tissues
Tell us where to treatTell us where to treat
Tell us how to treatTell us how to treat
Based on ResonanceBased on Resonance
RESONANCERESONANCE
Kernspintomograph (MRT)Kernspintomograph (MRT)
The Facts The Facts
Behind a Successful Medical ClinicBehind a Successful Medical Clinic
Specific pulsing electromagnetic fieldsSpecific pulsing electromagnetic fields
Footnotes:Footnotes:
1. Bischof, Marco: Biophotonen. Das Licht in unseren1. Bischof, Marco: Biophotonen. Das Licht in unseren
Zellen, 1995, Zweitausendeins VerlagZellen, 1995, Zweitausendeins Verlag
2. Popp, F.A./Nagl, W./Li, K.H./Scholz, W./ Weingärtner, O./ Wolf, R.: 2. Popp, F.A./Nagl, W./Li, K.H./Scholz, W./ Weingärtner, O./ Wolf, R.:
Biophoton Biophoton emission: New evidence for coherence and DNA as emission: New evidence for coherence and DNA as
source (1984)source (1984)
3. Cittert, P.H. van: Physica, Vol 1 (1934), S.201; Zernike , F.: 3. Cittert, P.H. van: Physica, Vol 1 (1934), S.201; Zernike , F.:
Physica, Vol. 5 (1938), S.785Physica, Vol. 5 (1938), S.785
4. Popp, F.A. : Biology of Light (1984) S. 75-76: Li/Popp, F.A.: Non-4. Popp, F.A. : Biology of Light (1984) S. 75-76: Li/Popp, F.A.: Non-
exponential decay law of radiation systems(1983) ; Li, K.H., Popp, exponential decay law of radiation systems(1983) ; Li, K.H., Popp,
F.A.,/ Nagl,W/ Klima, H. : Indications of optical coherenceF.A.,/ Nagl,W/ Klima, H. : Indications of optical coherence