Volume : 08, Issue : 04, April – 2021



Authors :

Dr. Raymond L Venter

Abstract :

It is only in the last few decades that the significance of electromagnetic fields (EM) interactions in biology and medicine has been fully realised. What we learn about the phenomenon of cellular function and its relation to a specific frequency of signaling is very little in depth. An ionized or electric signal is far more than just a new type of tool; it represents a whole new way of doing things. Additionally, the broadening of the scope of EM provides greater knowledge and therefore empowers the people in the profession by showing that EM also empowers the professionals more. It was deduced from Dr. Zhadin’s finding that magnetic intensities have both innate and exogenous sources, which suggests that ultrasmall regulation is therefore an endogenously effective principle. This conclusion was drawn because of the evidence that extracellular and intracellular magnetic therapies have both innate and exogenous sources, and endogenetic efficacy, implying that the properties of ultrasmall regulation are intrinsic. Whereas earlier researchers investigated the possibility of finding useful signals of electromagnetic generators in the nineteenth century, Matteucci conducted pioneering work in the twentieth that identified ones of medical significance in living systems in the first half of the century. Today, biological data are regulated using an ion-field cyclotron method, where circular polarizations are built up and multi-polar fields are applied to expand. the field of applied electromyography (EM).
Keywords: Bio resonance, stem cell differentiation, ion cyclotron resonance, electromagnetic medicine, Cell repair, cell growth

Cite This Article:

Please cite this article in press Raymond L Venter., Environmental Energy For Cellular Growth And Repair Especially By Bio-Resonance Focused Ultrasound: A Literature Review., Indo Am. J. P. Sci, 2021; 08(04).

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1. Raymond L Venter., Focused Ultrasound Involving The Usage Of Cell Resonance To Understand The Effect And Its Use As A Therapy For Disease Modification.,Indo Am. J. P. Sci, 2021; 08(03).
2. Aarholt E, Flinn EA, Smith CW (1981). Effects of low frequency magnetic fields on bacterial growth rate. Phys Med Biol 26:613– 621.
3. Adair RK (1991). Constraints on biological effects of weak extremely-low-frequency electromagnetic fields. Physical Rev A 43:1039– 1048.
4. Adey WR, Bawin S (1982). Binding and release of brain calcium by low-level electromagnetic fields: a review. Radio Sci 17(5S):149S–157S.
5. Adey WR, Bawin FM, Lawrence AF (1982). Effects of weak, amplitude-modulated fields on calcium efflux from awake cat cerebral cortex. Bioelectromagnetics 3:295– 308.
6. Alberto D, Busso I, Crotti G, Gandini M, Garfagnini R, Giudici P, Gnesi I, et al. (2008). Effects of static and low-frequency alternating magnetic fields on the ionic electrolytic currents of glutamic acid aqueous solution. Electromagnetic Biology and Medicine 27:25– 39.
7. Andocs G, Szasz O, Szasz A (2009). Oncothermia treatment of cancer: from the laboratory to the clinic. Electromagn Biol Med 28:148– 165.
8. Astumian RD, Robertson B (1989). Nonlinear effect of an oscillating electric field on membrane proteins. J Chem Phys 72:4891– 4899.
9. Astumian RD, Weaver JC, Adair RK (1995). Rectification and signal averaging of weak electric fields by biological cells. Proc Natl Acad Sci USA 92(9):3740– 3743.
10. Ayrapetyan R, Grigorian K, Avanesyan A, Stamboltsian K (1994). Magnetic field alter electrical properties of solutions and their physiological effects. Bioelectromagnetics 15:133– 142.
11. Baker B, Spadaro J, Marino A, Becker RO (1974). Electrical stimulation of articular cartilage regeneration. Ann N Y Acad Sci 238:491–499.
12. Baker B, Becker RO, Spadaro J (1974). A study of electrochemical enhancement of articular cartilage repair. Clin Orthop Relat Res 102:251– 267.
13. Barbieri M (2004). The definition of information and meaning two possible boundaries between physics and biology. Riv Biol 97:91– 109.
14. Barnes FS (1996). Effect of electro-magnetic field on the rate of chemical reactions. Biophysics 41:801– 880.
15. Basset CAL (1993). Beneficial effects of electromagnetic fields. J Cell Biochem 51:387–393.
16. Basset CAL, Pawluk RJ, Pilla AA (1974). Augmentation of bone repair by inductively coupled electromagnetic field. Science 184:575–579.
17. Becker RO (1967). The electrical control of growth processes. Med Times 96:657– 669.
18. Becker RO (1972). Stimulation of partial limb regeneration in rats. Nature 235:109– 111.
19. Becker RO (1987). Electromagnetism and the revolution in medicine. Acupunct Electrother Res 12(1): 75– 79.
20. Becker RO (2002). Induced dedifferentiation: a possible alternative to embryonic stem cell transplant. NeuroRehabilitation 17(1):23–31.
21. Becker RO (2004). Exploring new horizons in electromedicine. J Altern Complement Med 10(1):17– 18.
22. Becker RO, Bachman CH (1965). Bioelectric effects in tissue. Clin Orthop Relat Res 43:251– 253.
23. Becker RO, Brown FM (1965). Photoelectric effects in human bone. Nature 206(991):1325– 1328.
24. Becker RO, Murray DG (1970). The electrical system regulating fracture healing in amphibians. Clin Orthop Relat Res 73:169– 198.
25. Becker RO, Spadaro JA (1972). Electrical stimulation of partial limb regeneration in mammals. Bull N Y Acad Med 48(4):627– 641.
26. Becker RO, Chapin S, Sherry R (1974). Regeneration of the ventricular myocardium in amphibians. Nature 248(444):145– 147.
27. Belova NA, Lednev VV (2000). Activation and inhibition of gravitropic response in plants by weak combined magnetic fields. Biophysics 45:1069– 1074.
28. Belyaev IY, Alipov ED (2001). Frequency-dependent effects of ELF on chromatin conformation in Escherichia coli cells and human lymphocytes. Biophys Biochim Acta 1526:269– 276.
29. Belyaev IY, Alipov YD, Harms-Ringdahl M (1997). Effects of zero magnetic field on the conformation of chromatin in human cells. Biophys Biochim Acta 1336:465– 473.
30. Berg H (1993). Electrostimulation of cell metabolism by low frequency electric and electromagnetic fields. Biolectrochem Bioener 31:1– 25.
31. Berg H, Zang L (1993). Electrostimulation in cell biology by low frequency electromagnetic fields. Electro Magnetobiol 12(2):147– 163.
32. Bersani F, editor. (1999). Electricity and magnetism in biology and medicine. New York: Kluwer Academic/Plenum Publishers.
33. Bertalanffy Lvon (1949). Open systems in physics and biology. Nature 163:384.
34. Bertalanffy Lvon (1950). The theory of open systems in physics and biology. Science 111:23– 29.
35. Bier M (2005). Gauging the strengths of power frequency fields against membrane electrical noise. Bioelectromagnetics 26:595– 609.
36. Bistolfi F (1987). Classification of possible targets of interaction of magnetic fields with living matter. Panminerva Med 29(1):71– 73.
37. Bistolfi F (1990). The bioelectronic connectional system (BCS): a therapeutic target for nonionizing radiation. Panminerva Med 32(1):10– 18.
38. Blackman CF, Benane SG, Rabinowitz JR, House DE, Joines WT (1985). A role for the magnetic field in the radiation-induced efflux of calcium ions from brain tissue in vitro. Bioelectromagnetics 6:327–337.
39. Blackman CF, Kinney LS, House DE, Joines WT (1989). Multiple power-density windows and their possible origin. Bioelectromagnetics 10:115– 128.
40. Blackman C, Benane S, House D, Elliot D (1990). Importance of alignment between local DC magnetic field and an oscillating magnetic field in response of brain tissue in vitro and in vivo.
41. Bioelectromagnetics 11:159– 167.
42. Blackman CF, Benane S, House D (1993a). Evidence for direct effect of magnetic fields on neurite outgrowth. FASEB J 7:801– 806.
43. Blackman CF, Benane S, House D (1993b). Frequency-dependent interference by magnetic fields of nerve growth factor-induced neurite outgrowth in PC-12 cells. Bioelectromagnetics 16:387–395.
44. Blackman CF, Blanchard JP, Benane SG, House DE (1994). Empirical test of an ion parametric resonance model for magnetic field interactions with PC-12 cells. Bioelectromagnetics 15:239– 260.
45. Blackman CF, Blanchard JP, Benane SG, House DE (1995). The ion parametric resonance model predicts magnetic field parameters that affect nerve cells. FASEB J 9:547– 551.
46. Blackman CF, Blanchard JP, Benane SG, House DE (1999). Experimental determination of hydrogen bandwidth for the ion parametric resonance model. Bioelectromagnetics 20(1):5– 12.
47. Blanchard JP, Blackman CF (1994). Clarification and application of an ion parametric resonance model for magnetic interaction with biological systems. Biolectromagnetics 15:217– 238.
48. Blank M, Soo L (1992). Threshold for inhibition of Na/K ATPase by ELF alternating currents.
49. Biolectromagnetics 13:329– 333.
50. Blank M, Soo L (1993a). The Na/K ATPase as a model for electromagnetic field effects on cells.
51. Bioelectrochem Bioenerg 30:85– 92.
52. Blank M, Soo L (1993b). The threshold for Na/K ATPase stimulation by electromagnetic fields.
53. Bioelectroch Bioenerg 40:63–65.
54. Bobkova NV, Novikov VV, Medvinskaya NI, Fesenko EE (2005). Reduction in the b-amyloid level in the brain under the action of weak combined fields in a model of Sporadic Alzheimer’s disease. Biophysics 540:52–57.
55. Brugemann H, editor. (1990). Bioresonance and multiresonance therapy (BRT). Brussels: Haug
56. International Publishing. Chou C-K, McDougall JA, Ahn C, Vora N (1997). Electrochemical treatment of mouse and rat fibrosarcomas with direct current. Bioelectromagnetics 18:14–24.
57. Cossarizza A, Monti D, Bersani F, Cadossi R, Sacchi Franceschi C (1989). Extremely low frequency pulsed electromagnetic fields increase cell proliferation in lymphocytes from young and aged subjects. Biochem Biophys Res Commun 160:692– 698.
58. Cossarizza A, Monti D, Bersani F, Paganelli R, Montagnani G, Cadossi R, Cantini M, Franceschi C (1989). Extremely low frequency pulsed electromagnetic fields increase interleukin-2 (IL-2) and IL-2 receptor expression in lymphocytes from old subjects. FEBS Lett 248:141– 144.