Q 1992 Gordon and Brcach Science Publishers S.A. Printed in the United S t a b of America
125-126 intern. J . Neuroscience, 1992, Vol. 67. Reprints available d m t l y from t k publixr Photocopying permitted by license only
Letter to the Editor EFFECT OF WEAK MAGNETIC FIELDS ON BIOLOGICAL SYSTEMS (Received March I I, 1992)
Int J Neurosci Downloaded from informahealthcare.com by ThULB Jena on 11/12/14 For personal use only.
Keywords: Weak magnetic fields; Jacobson resonance; pineal gland; melatonin; Parkinson’s disease; epilepsy.
To The Editor: Following the intuition and inspiration of Albert Einstein, it became clear to me in 1979 that the unification of gravity and electromagnetism could only be achieved through a purely algebraical method (Jacobson, 1983). Einstein (1977) felt that the success of the Heisenberg method pointed in this direction. The equation that sets gravitational and electromagnetic potential in dual resonance is represented as mc2 = Bvl coulomb (Jacobson, 1986). The application of this equation to clinical medicine pointed clearly to the necessity of utilizing picotesla or gauss magnetic fields. While these weak magnetic fields have been measured in the early 1980’s, no one could conceive yet in 1979 of the application of such weak signals to human disease. Since 1979, I explained that these weak physiologic magnetic fields interacted with biological systems to produce gravity waves, and the mathematical electromagnetic photon/phonon transductions resulted in reorientations of atomic crystal lattice structures of critical molecules like genes, homeoboxes, enzymes, and peptide hormone trophic factors. In 1985, Professor William Yamanashi named my equation Jacobson resonance. I showed clear mathematical relations to Zeeman resonance and cyclotron resonance (Jacobson, 1983; 1986; 1987 a; b; 1988; 1991 a; b). While there has been a great revival of interest in the effects of non-ionizing electromagnetic radiation on biological systems during the past decade, experiments have been limited to the usage of magnetic fields about and stronger than the geomagnetic field. Recently, Professor Reuven Sandyk reported on the efficacy of 2 x gauss fields in the treatment of epilepsy and Parkinson’s disease (cf. Anninos et al., 1991; Sandyk et al., in press; Sandyk, in press a; Sandyk, in press b). Frequencies of 27 Hz have been utilized. Definitive correlations between these frequencies, picotesla magnetic fields, the gyromagnetic ratio of the electron and masses of critical molecules like melatonin are demonstrable with Jacobson resonance and cylotron resonance (Jacobson, submitted for publication). It is now possible to explore a completely new avenue in the wonderous connection between picotesla magnetic fields and the pineal gland. The mechanisms by which extremely low frequency fields produce bioeffects are explicable in terms of Jacobson resonance. Additionally, the dark soliton question is also answerable. The fact that picotesla magnetic fields have finally been shown to be an important adjunctive modality by which to treat a variety of human disorders points to the verification of Jacobson resonance as a fundamental natural law. It is hoped that Professor Sandyk’s work will serve as a springboard to further explore Correspondence to Jerry I. Jacobson, Ph.D., D.M.D.Chairman, Institute of Theoretical Physics and Advanced Studies for Biophysical Research, 153 Raintree Trail, Jupiter, Florida 33458, U.S.A. 125
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J. I . JACX)RSON
the clinical possibilities inherent in the utilization of exogenously sourced physiologic magnetic fields.
Int J Neurosci Downloaded from informahealthcare.com by ThULB Jena on 11/12/14 For personal use only.
REFERENCES Anninos, P. A , , ?’sagas, N., Sandyk, R . & Derpapas, K. (1991). Magnetic stimulation in the treatment of partial seizures. International Journal of Neuroscience, 60, 141- 17 I . Einstein, A. (1977). Out of my later years (p. 92). New York: Philosophical Library. Jacobson. J. I. (1983). The secret of life, perspectivism in science. New York: Philosophical Library. Jacobson, J. I. (1986). mc? = Bvl coulomb: gravitational and EM potential in dual resonance. Indian Journal of Theoretical Physics, 34, 23 1-239. Jacobson, J . I. (1987 a).Oncogenes and magnetic resonance energies unified algebraically. PanMinerva Medica-Europa Medica, 29, 97-104. Jacobson, J. I. (1987 b). A testable theoretical model for the mechanism of magneto therapy. PanMinerva Medica-Europa Medica, 29, 263-270. Jacobson, J. I. (1988). Normal and diseased states related to interdependence of electromagnetic fields, growth and repair and genetic regulation of metabolic function. Indian Journal of Biochemist. & Biophvsics, 25, 442-446. Jacobson, J. I. (1991 a). A look at the possible mechanism of the potential of magneto therapy. Journal of Theoretical Biology, 149, 97- 120. Jacobson, J. I. ( 1 9 9 1 h). Magneto recrystallization of genomic and associated structures potentially applicative to such diverse concerns as cancer, AIDS, and CNS regeneration. Chinese Medical Journal, 104, 1025-1032. Jacobson, J. I. (1992). The question of gravity in the human cell. Its possible role in normal cell division and cancer and the pineal gland connection. International Journal of Neuroscience (submitted for publication). Sandyk, R. (in press a).Weak magnetic fields in the treatment of Parkinson’s disease with the ‘on-off” phenomenon. International Journal of Neuroscience. Sandyk, R . (in press b). Weak magnetic fields as a novel therapeutic modality in Parkinson’s disease. International Journal of Neuroscience. JERRY I. JACOBSON Institute of Theoretical Physics and Advanced Studies for Biophysical Research Jupiter, Florida, U.S.A.
125-126 intern. J . Neuroscience, 1992, Vol. 67. Reprints available d m t l y from t k publixr Photocopying permitted by license only
Letter to the Editor EFFECT OF WEAK MAGNETIC FIELDS ON BIOLOGICAL SYSTEMS (Received March I I, 1992)
Int J Neurosci Downloaded from informahealthcare.com by ThULB Jena on 11/12/14 For personal use only.
Keywords: Weak magnetic fields; Jacobson resonance; pineal gland; melatonin; Parkinson’s disease; epilepsy.
To The Editor: Following the intuition and inspiration of Albert Einstein, it became clear to me in 1979 that the unification of gravity and electromagnetism could only be achieved through a purely algebraical method (Jacobson, 1983). Einstein (1977) felt that the success of the Heisenberg method pointed in this direction. The equation that sets gravitational and electromagnetic potential in dual resonance is represented as mc2 = Bvl coulomb (Jacobson, 1986). The application of this equation to clinical medicine pointed clearly to the necessity of utilizing picotesla or gauss magnetic fields. While these weak magnetic fields have been measured in the early 1980’s, no one could conceive yet in 1979 of the application of such weak signals to human disease. Since 1979, I explained that these weak physiologic magnetic fields interacted with biological systems to produce gravity waves, and the mathematical electromagnetic photon/phonon transductions resulted in reorientations of atomic crystal lattice structures of critical molecules like genes, homeoboxes, enzymes, and peptide hormone trophic factors. In 1985, Professor William Yamanashi named my equation Jacobson resonance. I showed clear mathematical relations to Zeeman resonance and cyclotron resonance (Jacobson, 1983; 1986; 1987 a; b; 1988; 1991 a; b). While there has been a great revival of interest in the effects of non-ionizing electromagnetic radiation on biological systems during the past decade, experiments have been limited to the usage of magnetic fields about and stronger than the geomagnetic field. Recently, Professor Reuven Sandyk reported on the efficacy of 2 x gauss fields in the treatment of epilepsy and Parkinson’s disease (cf. Anninos et al., 1991; Sandyk et al., in press; Sandyk, in press a; Sandyk, in press b). Frequencies of 27 Hz have been utilized. Definitive correlations between these frequencies, picotesla magnetic fields, the gyromagnetic ratio of the electron and masses of critical molecules like melatonin are demonstrable with Jacobson resonance and cylotron resonance (Jacobson, submitted for publication). It is now possible to explore a completely new avenue in the wonderous connection between picotesla magnetic fields and the pineal gland. The mechanisms by which extremely low frequency fields produce bioeffects are explicable in terms of Jacobson resonance. Additionally, the dark soliton question is also answerable. The fact that picotesla magnetic fields have finally been shown to be an important adjunctive modality by which to treat a variety of human disorders points to the verification of Jacobson resonance as a fundamental natural law. It is hoped that Professor Sandyk’s work will serve as a springboard to further explore Correspondence to Jerry I. Jacobson, Ph.D., D.M.D.Chairman, Institute of Theoretical Physics and Advanced Studies for Biophysical Research, 153 Raintree Trail, Jupiter, Florida 33458, U.S.A. 125
126
J. I . JACX)RSON
the clinical possibilities inherent in the utilization of exogenously sourced physiologic magnetic fields.
Int J Neurosci Downloaded from informahealthcare.com by ThULB Jena on 11/12/14 For personal use only.
REFERENCES Anninos, P. A , , ?’sagas, N., Sandyk, R . & Derpapas, K. (1991). Magnetic stimulation in the treatment of partial seizures. International Journal of Neuroscience, 60, 141- 17 I . Einstein, A. (1977). Out of my later years (p. 92). New York: Philosophical Library. Jacobson. J. I. (1983). The secret of life, perspectivism in science. New York: Philosophical Library. Jacobson, J. I. (1986). mc? = Bvl coulomb: gravitational and EM potential in dual resonance. Indian Journal of Theoretical Physics, 34, 23 1-239. Jacobson, J . I. (1987 a).Oncogenes and magnetic resonance energies unified algebraically. PanMinerva Medica-Europa Medica, 29, 97-104. Jacobson, J. I. (1987 b). A testable theoretical model for the mechanism of magneto therapy. PanMinerva Medica-Europa Medica, 29, 263-270. Jacobson, J. I. (1988). Normal and diseased states related to interdependence of electromagnetic fields, growth and repair and genetic regulation of metabolic function. Indian Journal of Biochemist. & Biophvsics, 25, 442-446. Jacobson, J. I. (1991 a). A look at the possible mechanism of the potential of magneto therapy. Journal of Theoretical Biology, 149, 97- 120. Jacobson, J. I. ( 1 9 9 1 h). Magneto recrystallization of genomic and associated structures potentially applicative to such diverse concerns as cancer, AIDS, and CNS regeneration. Chinese Medical Journal, 104, 1025-1032. Jacobson, J. I. (1992). The question of gravity in the human cell. Its possible role in normal cell division and cancer and the pineal gland connection. International Journal of Neuroscience (submitted for publication). Sandyk, R. (in press a).Weak magnetic fields in the treatment of Parkinson’s disease with the ‘on-off” phenomenon. International Journal of Neuroscience. Sandyk, R . (in press b). Weak magnetic fields as a novel therapeutic modality in Parkinson’s disease. International Journal of Neuroscience. JERRY I. JACOBSON Institute of Theoretical Physics and Advanced Studies for Biophysical Research Jupiter, Florida, U.S.A.
