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2016 | 56 | 1-20
Article title

Hidden Connections Between NanoTesla Magnetic Fields, Cosic Molecular Resonance, and Photonic Fields Within Living Systems

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EN
Abstracts
EN
The interfaces between molecules and the interactions between cells involve very small energies (~10-20 J) and photon flux densities (~10-12 W•m-2) that ultimately control the dynamics and health of the human body. Within the environment there is an increment (± 3 nT) of weak magnetic field fluctuations whose energies within the volume of the human brain display the capacities to affect its properties through nuclear spins in neural membranes. There is a conservation of energy. Within the same volume when there are increases in photon flux densities from cells and human cerebrums there are decreases of interfacial geomagnetic field intensities within the nanoTesla range. The spectral power densities of the sequential quantifications of pseudopotentials of the amino acids that compose proteins and the nucleotides that construct DNA and RNA predict the functions of molecular pathways as electromagnetic resonances. They operate through these small energies, photon flux densities, and fluctuating magnetic fields. Whereas metabolic-level energies operate the mechanics of the multivariate molecular pathways for cell signaling the photon wavelengths predicted by the Cosic Resonant Recognition Model may be the templates and the initiators. The involvement of specific peaks of photon wavelengths that are the energetic equivalents of molecular structures containing intrinsic phase-modulations creates the conditions for excess correlations (“entanglement”) and potential non-locality within the total human environment. This alternative perspective may facilitate developments of different strategies and technologies for solving the challenges of global public health in the 21st century.
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Year
Volume
56
Pages
1-20
Physical description
Contributors
  • Behavioural Neuroscience, Biomolecular Sciences and Human Studies Programs, Laurentian University, Sudbury, Ontario, P3E 2C, Canada, mpersinger@laurentian.ca
References
  • [1] Cherry, N. 2002. Schumann Resonances: a plausible biophysical mechanism for human health effects of solar/geomagnetic activity. Natural Hazards 2002, 26, 279-311.
  • [2] Koenig, H. L.; Krueger, A. P.; Lonag, S.; Sonning, W. Biologic effects of environmental electromagnetism. Springer-Verlag New York, 1981.
  • [3] Babayev, E. S.; Allahverdiyeva, A. A. Effects of geomagnetic activity variations on the physiological and psychological state of functionally healthy humans: some results of the Azerbijani studies. Advances in Space Research 2007, 40, 1941-1951.
  • [4] Adey, W. R. Tissue interactions with nonionizing electromagnetic fields. Physiological Reviews, 1981, 61, 435-509.
  • [5] Rajaram, M.; Mitra, S. Correlation between convulsive seizure and geomagnetic activity. Neuroscience Letters, 1981, 24, 187-191.
  • [6] Persinger, M. A.; ELF and VLF electromagnetic field effects. Plenum Press, N.Y., 1974.
  • [7] Saroka, K. S.; Caswell, J. M.; Lapointe, A.; Persinger, M. A. Greater electroencephalographic coherence between left and right temporal lobe structures during increased geomagnetic activity. Neuroscience Letters 2014, 560, 126-130.
  • [8] Michon, A. L.; Persinger, M. A. Experimental simulation of the effects of increased geomagnetic activity upon nocturnal seizures in epileptic rats. Neuroscience Letters, 1997, 224, 53-56.
  • [9] Mulligan, B. P.; Hunter, M. S.; Persinger, M. A. Effects of geomagnetic activity and atmospheric power variations on quantitative measures of brain activity: replication of the Azerbaijani studies. Advances in Space Research, 2010, 45, 940-948.
  • [10] Mulligan, B. P.; Persinger, M. A. Experimental simulation of the effects of sudden increases in geomagnetic activity upon quantitative measures of human brain activity: validation of correlational studies. Neuroscience Letters, 2012, 516, 54-56.
  • [11] Caswell, J. M.; Singh, M.; Persinger, M. A. Simulated sudden increase in geomagnetic activity and its effects on heart rate variability: experimental verification of correlational studies. Life Sciences in Space Research, 2016, in revision.
  • [12] Dimitrova, S.; Angelov, I.; Petrova, E. Solar and geomagnetic activity effects on heart rate variability. Natural Hazards, 2013, 69, 25-37.
  • [13] Ossenkopp, K.-P.; Barbieto, R. Bird orientation and the geomagnetic field: a review. Neuroscience and Biobehavioral Reviews, 1978, 2, 255-270.
  • [14] Persinger, M. A.; Richards, P. M. Vestibular experiences of humans during brief periods of partial sensory deprivation are enhanced when daily geomagnetic activity exceeds 15-20 nT. Neuroscience Letters, 1995, 194, 69-72.
  • [15] Booth, J. C.; Koren, S. A.; Persinger, M. A. Increased feelings of a sensed presence and increased geomagnetic activity at the time of the experience during exposures to transcerebral weak complex magnetic fields. International Journal of Neuroscience, 2005, 115, 625-648.
  • [16] Adey, W. R. Tissue interaction with nonionizing electromagnetic fields. Physiological Reviews, 1981, 433-509.
  • [17] St-Pierre, L. S.; Parker, G. H.; Bubenik, G. A.; Persinger, M.A. Enhanced mortality of rat pups following inductions of epileptic seizures after perinatal exposures to 5 nT, 7 Hz magnetic fields. Life Sciences, 2007, 81, 1496-1500.
  • [18] Persinger, M. A.; Saroka, K. S. Quantitative support for the convergence of intrinsic energies from applied magnetic fields and “noise” fluctuations of Newton’s gravitational value within the human brain. International Letters of Chemistry, Physics and Astronomy, 2014, 19, 181-190.
  • [19] Vladimirskii, B. M. Measurements of the gravitational constant and heliogeophysical electromagnetic perturbations. Biophysics, 1996, 40, 915-923.
  • [20] Persinger, M. A.; St-Pierre, L. S. Is there a geomagnetic component involved with the determination of G? International Journal of Geosciences, 2014, 5, 450-452.
  • [21] Quinn, T.; Parks, H.; Speake, C.; David, R. Improved determination of G using two methods. Physics Review Letters, 2013, 111, 101102.
  • [22] Dotta, B. T.; Saroka, K. A.; Persinger, M. A. Increased photon emission from the head while imagining light in the dark is correlated with changes in electroencephalographic power: support for Bokkon’s biophoton hypothesis. Neuroscience Letters, 2012, 513, 151-154.
  • [23] Isojima, Y.; Isoshima, K.; Nagi, K.; Kikuchi, H.; Nakagawa, H. Ultraweak biochemiluminescence detected from hippocampal slices. Neuroreport, 1995, 6, 658-660.
  • [24] Hunter, M. D.; Mulligan, B. P.; Dotta, B. T.; Saroka, K. S.; Lavallee, C. F.; Koren, S. A.; Persinger, M. A. Cerebral dynamics and discrete energy changes in the personal physical environment during intuitive-like states and perceptions. Journal of Consciousness Exploration & Research, 2010, 1, 1179-1197.
  • [25] Bokkon, I. Dreams and neuroholography: an interdisciplinary interpretation of development of the homeotherm state in evolution. Sleep and Hypnosis, 2005, 7, 61-76.
  • [26] Costa, J.; Dotta, B. T.; Persinger, M. A. Lagged coherence of photon emissions and spectral power densities between cerebral hemispheres of human subjects during rest conditions: phase shift and quantum possibilities. World Journal of Neuroscience, 2016, 6, 119-125.
  • [27] Persinger, M. A.; Dotta, B. T.; Saroka, K. S.; Scott, M. A. Congruence of energies for cerebral photon emissions, quantitative EEG activities and 5 nT changes in proximal geomagnetic field support spin-based hypothesis of consciousness. Journal of Consciousness Exploration & Research, 2013, 4, 1-24.
  • [28] Llinas, R. R.; Pare, D. Of dreaming and wakefulness. Neuroscience, 1991, 44, 521-535.
  • [29] Belisheva, N. K.; Popov, A. N.; Petukhova, N. V.; Pavlova, L.P.; Osipov, K. S.; Tkachenko, S. E.; Baranova, T. I. Quantitative and qualitative evaluation of the effect of geomagnetic field variations on the functional state of the human brain. Biophysics, 1995, 40, 1007-1014.
  • [30] Persinger, M. A.; Dotta, B. T.; Karbowski, L. M.; Murugan, N.J. Inverse relationship between photon flux densities and nanoTesla magnetic fields over cell aggregates: quantitative evidence of energetic conservation. FEBS Open, 2015, 5, 413-418.
  • [31] Nishida, K.; Kobayashi, N.; Fukao, Y. Resonant oscillations between the solid earth and the atmosphere. Science, 2000, 287, 2244-2246.
  • [32] Persinger, M. A. Potential gravitational-solar electromagnetic spectral radiance interaction as the source of the earth’s background free oscillations. International Letters of Chemistry, Physics and Astronomy, 2014, 2, 11-14.
  • [33] Hu, H.; Wu, M. Action potential modulation of neural spin networks suggests possible role of spin in consciousness. NeuroQuantology, 2004, 4, 309-317.
  • [34] Persinger, M. A. 10-20 Joules as a neuromolecular quantum in medicinal chemistry: an alternative approach to the myriad of molecular pathways. Current Medicinal Chemistry, 2010, 17, 3094-3098.
  • [35] Decoursey, T. E. Voltage-gated proton channels and other proton transfer pathways. Physiological Reviews, 2003, 83, 475-579.
  • [36] Dotta, B. T.; Lafrenie, R. M.; Karbowski, L. M.; Persinger, M. A. Photon emission from melanoma cells during brief stimulation of patterned magnetic fields: is the source coupled to rotational diffusion within the membrane? General Physiology and Biophysics, 2014, 33, 63-73.
  • [37] Persinger, M. A. The prevalence and significance of ~10-20 J and ~10-12 W•m-2 as convergent/divergent nodal units in the universe. International Letters of Chemistry, Physics and Astronomy, 2015, 61, 94-100.
  • [38] Popp, F. A. Coherent photon storage in biological systems. In Popp, F. A.; Becker, G.; Konig, H. L.; Peschka, W (eds). Electromagnetic Bioinformation. Urban and Schwarzenberg: Munchen-Wien-Baltimore, 1979, pp. 123-149.
  • [39] Murugan, N. J.; Karbowski, L. M.; Persinger, M. A. Serial pH increments (~20 to 40 milliseconds) in water during exposures to weak, physiologically patterned magnetic fields: implications for consciousness. Water, 2014, 6, 45-60.
  • [40] Dotta, B. T.; Buckner, C. A.; Cameron, D.; Lafrenie, R. F.; Persinger, M. A. Biophoton emission from cell cultures: biochemical evidence for the plasma membrane as the primary source. General Physiology and Biophysics, 2011, 30, 301-309.
  • [41] Tilbury, R. N.; Quickenden, T. I. Spectral and time dependence studies on the ultraweak bioluminescence emitted by the bacterium Escherichia coli. Photochemistry and Photobiology, 1988, 47, 145-150.
  • [42] Cosic, I. Macromolecular bioactivity: Is it resonant interaction between macromolecules? - Theory and application. IEEE Transactions On Biomedical Engineering 1994, 41, 1101-1114.
  • [43] Cosic, I.; Cosic, D.; Lazar, K. Environmental light and its relationship with electromagnetic resonances of biomolecular interactions, as predicted by the Resonant Recognition Model. International Journal of Environmental Research and Public Health 2016 13, 647 (10 pages).
  • [44] Seel, F. Atomic structure and chemical bonding. Science Paperbacks and Methuen & Co: London, 1966.
  • [45] Dotta, B. T.; Murugan, N. J; Karbowski, L. M.; Lafrenie, R. M.; Persinger, M. A. Shifting wavelengths of ultraweak photon emissions form dying melanoma cells: their chemical enhancement and blocking are predicted by Cosic’s theory of resonant recognition model for macromolecules. Naturwissenchaften 2014, 101, 87-94.
  • [46] Karbowski, L. M.; Murugan, N. J.; Persinger, M. A. Novel Cosic resonance (standing wave) solution for components of the JAK-STAT cellular signaling pathway: a convergence of spectral density profiles. FEBS OpenBio, 2015, 5, 245-250.
  • [47] Garner, A. J. P.; Vedral, V. The ultimate physical limits to reversibility. Quantum Physics, 2016, arXiv:1604.03208v1.
  • [48] Persinger, M. A.; Murugan, N. J.; Karbowski, L. M. Combined spectral resonances of signaling proteins’ amino acids in the ERK-MAP pathway reflect unique patterns that predict peak photon emissions and universal energies. International Letters of Chemistry, Physics and Astronomy, 2015, 43, 10-25.
  • [49] Persinger, M. A. Thixotropic phenomena in water: quantitative indicators of Casimir-magnetic transformations from vacuum oscillations (virtual particles). Entropy, 2015, 17, 6200-6212.
  • [50] Wei, L. Y. Molecular mechanisms of nerve excitation and conduction. Bulletin of Mathematical Biophysics, 1969, 31, 39-58.
  • [51] Del Giudice, E.; Preparata, G. Coherent dynamics in water as a possible explanation of biological membrane formation. Journal of Biological Physics, 1994, 20, 105-116.
  • [52] Karbowski, L. M.; Murugan, N. J.; Persinger, M. A. Experimental evidence that specific photon energies are “stored” in malignant cells for an hour: the synergism of weak magnetic field-LED wavelength pulses. Biology and Medicine, 2016, 8:1
  • [53] Murugan, N. J.; Karbowski, L. M.; Dotta, B. T.; Persinger, M. A. Delayed shifts in pH responses to weak acids in spring water exposed to circular rotating magnetic fields: a narrow band intensity-dependence. International Research Journal of Pure and Applied Chemistry, 2015, 5, 131-139.
  • [54] Sedlak, M. Real-time monitoring of the origination of multimacroion domains in polyelectrolyte solutions. Journal of Chemical Physics, 2005, 122, 151002.
  • [55] Verdel, N.; Jerman, I.; Bukovec, P. The “autothixotropic” phenomenon of water and its role in proton transfer. International Journal of Molecular Sciences, 2011, 12, 7481-7494.
  • [56] Bordag, M.; Mohideen, U.; Mostepanenko, V. M. New developments in the Casimir effect. Physics Reports, 2001, 353, 1-205.
  • [57] Pollack, G. H. The role of aqueous interfaces in the cell. Advances in Colloid and Interface Science, 2003, 103, 173-196.
  • [58] Chai, B-H.; Zheng, J-M.; Zhao, Q.; Pollack, G. H. Spectroscopic studies of solutes in aqueous solution. Journal of Physical Chemistry, 2008, 112, 2242-2247.
  • [59] Chair, B.; Yoo, H.; Pollack, G.H. Effect of radiant energy on near-surface water. Journal of Physical Chemistry, 2009, 113, 13953-13958.
  • [60] Murugan, N. J.; Karbowski, L. M.; Lafrenie, R. M.; Persinger, M. A. Maintained exposure to spring water but not double distilled water in darkness and thixotropic conditions to weak (1 microTesla) temporally patterned magnetic fields shift photon spectroscopic wavelengths: effects of different shielding materials. Journal of Biophysical Chemistry, 2015, 6, 14-28.
  • [61] Tu, L-C.; Luo, J.; Gillies, G. T. The mass of the photon. Reports on Progress in Physics, 2005, 68, 77-130.
  • [62] Persinger, M. A. Convergent calculations that dark solutions are reflective of mass-energy yet to occur. International Journal of Astronomy and Astrophysics, 2012, 2, 125-128.
  • [63] Persinger, M. A.; Koren, S. A. Dimensional analyses of geometric products and the boundary conditions of the universe: implications for a quantitative value for the latency to display entanglement. The Open Astronomy Journal, 2013, 6, 10-13.
  • [64] Persinger, M. A.; Koren, S. A. Evidence for a causal relationship between Mach’s Principle and the quantitative latency for universal entanglement. International Letters of Chemistry, Physics and Astronomy, 2014, 15, 80-86.
  • [65] Baron, J.; Campbell, W. C.; DeMille, D.; Doyle, J. M.; Gabrielse, G.; Gurevich, Y. V.; Hess, P. W., et al. Order of magnitude smaller limit on the electric dipole moment of the electron. Science, 2014, 343, 269-272.
  • [66] Rouleau, N.; Persinger, M. A. Local electromagnetic fields exhibit temporally non-linear, east-west oriented 1 to 5 nT diminishments with a toroid: empirical measurements and quantitative solutions indicating a potential mechanism for excess correlation. Journal of Electromagnetic Analysis and Applications, 2015, 7, 19-30.
  • [67] Rouleau, N.; Carniello, T.; Persinger, M A. Non-local pH shifts and shared changing angular velocity magnetic fields: discrete energies and the importance of point durations. Journal of Biophysical Chemistry, 2014, 5, 44-53.
  • [68] Dotta, B. T.; Murugan, N. J.; Karbowski, L. M.; Persinger, M. A. Excessive correlated shifts in pH with distal solutions sharing phase-uncoupled angular accelerating magnetic fields: macro-entanglement and information transfer. International Journal of Physical Sciences, 2013, 8, 1783-1787.
  • [69] Dotta, B. T.; Persinger, M. A. “Doubling” of local photon emissions when two simultaneous, spatially separated, chemiluminescent reactions share the same magnetic field configurations. Journal of Biophysical Chemistry, 2012, 3, 72-80.
  • [70] Wang, C.; Gao, Y. Y.; Reinhold, P.; Heeres, R. W.; Ofek, N.; Chou, K.; Axline, C., et al. A Schrodinger cat living in two boxes. Science, 2016, 352, 1087-1091.
  • [71] Persinger, M. A.; Dotta, B. T.; Murugan, N. J.; Karbowski, L. M.; Koren, S. A. Rotational frequency matching of the energy of the changing angular velocity magnetic field intensity and the proton magnetic moment produces a ten fold increased excess correlation in pH shifts in spring water. NeuroQuantology, 2016, 14, 1-8.
  • [72] Murugan, N. J.; Dotta, B. T.; Karbowski, L. M.; Persinger, M. A. Conspicuous bursts of photon emissions in malignant cell cultures following injections of morphine: implications for cancer treatment. International Journal of Current Research, 2014, 6, 10588-10592.
  • [73] Trushin, M. V. Culture-to-culture physical interactions causes the alteration in red and infrared light stimulation of Escherichia coli growth rate. Journal of Microbiological Immunological Infections, 2003, 36, 149-152.
  • [74] Fels, D. Cellular communication through light. PLoS One, 2009, 4:e5086.
  • [75] Kahn, D.; Pace-Schott, E. F.; Hobson, J. A. Consciousness in waking and dreaming: the roles of neuronal oscillation and neuromodulation in determining similarities and differences. Neuroscience, 1997, 78, 13-38.
  • [76] Collins, M. W. G.; Persinger, M. A. Enhanced power within the default mode network in normal subjects with elevated scores on the egocentric scale. The Open Neuroimaging Journal, 2014, 8, 5-10.
  • [77] Pitkanen, M. TGD perspectives of nonlocality in quantum theory, biology, neuroscience and remote mental interactions. Journal Consciousness Exploration & Research, 2016, 7, 436-478.
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bwmeta1.element.psjd-e3b1d38e-0ff8-4f62-894b-50daa6482b02
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