Saratov JOURNAL of Medical and Scientific Research

Experimental study of the bioeffects of micropolarization current as a result of the use of metallic conductors in irradiating a rabbit's head with electromagnetic field of non-thermal intensity

Year: 2019, volume 15 Issue: №4 Pages: 994-998
Heading: Тhematic supplement Article type: Original article
Authors: Lukyanova S.N., Fomina T.V., Veselovskiy I.A.
Organization: State Research Center— Burnasyan Federal Medical Biophysical Center of Federal Medical Biological Agency
Summary:

The purpose of the study is to experimentally evaluate the impact of metal electrodes and wires on the brain bioelectric activity indicators as a result of rabbit head irradiation with electromagnetic field (EMF) of non-thermal intensity. Material and Methods. Studies conducted on rabbits. Electromagnetic field: 10 GHz, continuous mode, PPS 200 mW/cm2, created by the high-frequency signal generator G4-121 with repeated exposures with different durations. Results. The probability of the development of the effects of current micropolarization is shown when using metallic conductors, which changes the result of the EMF action. It depends on the number of electrodes and the location of wires relative to the field lines. Conclusion. We substantiated the possibility of the influence of metal electrodes on the bioelectrical activity of the brain by inducing a micropolar current under conditions of irradiation of the head with an electromagnetic field in the course of experiments on rabbits.

Bibliography:
1. Napp A, Stunder Д, Maytin M, et al. Are patients with cardiac implants protected against electromagnetic interference in daily life and occupational environment? Eur Heart J 2015 Jul 21; 36 (28): 1798-804.
2. Ribatti V, Santini L, Forleo G, et al. Electromagnetic interference in the current era of cardiac implantable electronic devices designed for magnetic resonance environment. Ital Cardiol (Rome) 2017 Apr; 18 (4): 295-304.
3. Al-Ademi YaTA, Davydov MV, Pulko ТА, et al. Rapid assessment of the effects of sources of electromagnetic pulses and spark discharges on imitators of biological tissues. Doklady BGUIR 2014; 5 (83): 44-8.
4. Seckier Т, Stunder D, Schikowsky С, et al. Effect of lead position and orientation on electromagnetic interference in patients with bipolar cardiovascular implantable electronic devices. Europace 2017 Feb 1; 19 (2): 319-28.
5. Implantable pacemakers Apollo. URL: http://www.cardioelectronica.com /assets/ rukovodstvo-stimuliator-apollo_new. pdf (дата обращения: 3 декабря 2018 г.).
6. Lukyanova SN. The electromagnetic field of the microwave range of non-thermal intensity as an irritant for the central nervous system. Moscow, 2015; 200 p.
7. Lukyanova SN. Bioelectric activity of the cortex and some subcortical formations during experimental neurosis. Journal of Higher Nervous Activity n. a. I. P. Pavlov 1976; 26 (3): 539-47.
8. Lukyanova SN. Intercenter relationships with experimental neurosis. Journal of Higher Nervous Activity n. a. I. P. Pavlov 1977; 27 (2): 345-7.
9. Khomskaya ED. Neuropsychology of emotions: hypotheses and facts. Voprosy Psihologii 2002; (4): 50-61.
10. Bagirova RM. Influence of brain neurochemical systems on frequency spectra of hippocampal theta rhythm. Bulletin of Moscow Region State University. Series: Natural Sciences 2014; (5): 8-13.
11. Buzsak IG, Moser El. Memory, navigation and theta rhythm in the hippocampal entorhinal system. Nature Neurosci 2013; 16: 130-8.
12. Vinogradova ОС. Hippocampus and memory. Moscow: Nauka, 1975; 333 p.
13. Lukyanova SN, Uiba VV. Therapy of Experimental Neurosis in Rabbits by Using the Electromagnetic Field in Comparison with Electrical and Chemical Nature. Medical radiology and radiation safety 2017; 62 (3): 5-12.
14. Garkavi LKh, Kvakina ЕВ, Ukolova MA. Adaptive reactions and body resistance. Rostov-na-Donu: Izd-vo Rost. Un-ta, 1979; 223 p.

AttachmentSize
2019_04-1_994-998.pdf525.14 KB

No votes yet