Low-intensity Microwave Radiation of Natural Substances for Physiotherapy

Source:
By:Yanenko Oleksiy , Peregudov S., Shevchenko K., Grubnik B., Golovchanska O.

DOI: https://doi.org/10.30564/jhp.v2i2.1885

Abstract:

The mechanisms of influence of physiotherapy procedures in ozokeriteparaffin therapy are considered in this paper. It is shown that microwave electromagnetic radiation formed by heated ozokerite-paraffin mixture is an important component of physiotherapy procedures. Using the experimental setup developed by the authors, the radiative abilities of ozokerite, paraffin and their mixtures in the microwave range were investigated. It was found that in the process of cooling the ozokerite-paraffin mixture, during the procedure, negative microwave fluxes occur, affecting the inflammatory processes in the patient’s body. The dependences of the microwave radiation level on the composition of the ozokerite-paraffin mixture are investigated. The results of experimental studies allowed us to evaluate the interaction of electromagnetic radiation of ozokerite-paraffin mixtures with human own electromagnetic radiation and to approach the choice of modes of therapeutic interaction more carefully.

References:

[1]Finogenov, S.M. Manual of physiotherapy. Kyi’v, Zdorov’ja, 1973: 260. (in Ukrainian) [2]Nikolova, L. Special physiotherapy. Sofija, Medicina i fizkul’tura Publ., 1983: 433. (in Russian). [3] Ulaschik, V.S., Lukomskii’, I.V. General Physiotherapy, Textbook. Minsk, Knizhnyi’ dom Publ., 2008: 512. (in Russian) [4] Ponomarenko, G.N. Physiotherapy: National guidelines. Moscow, GEOTAR Media, 2009: 864. (in Russian) [5] Yanenko, O.P, Peregudov, S.M., Fedotova, I.B., Golovchanska, O.D. Equipment and technologies of low intensity millimeter therapy. Vіsnik NTUU “KPІ”. Serіya - Radіotehnіka. Radіoaparatobuduvannja, 2014(59): 103-110. [6] Rojas, J.C., Gonzalez-Lima, F. Low-level light therapy of the eye and brain. Eye and Brain, 2011, 3: 49- 67. [7] Yanenko, O. Low-intensive microwave signals in biology and medicine. Journal of Human Physiology, 2011, 01(01): 29-41. [8] Korobov, A.M., Korobov, V.A., Lesnaja, T.A. Phototherapeutic devices of Korobov “Barva” series. Khar’kov, V.N. Karazin National University Publ., 2008: 175. (in Russian) [9] Sit’ko S.P. eds., Skripnik Yu.A., Yanenko A.F. Instrumental provision of modern technology of quantum medicine. Kiev, FADA LTD Publ., 1999: 199. (in Russian). [10] SkripnikYu.A., YanenkoA.F., ManoilovV.F., KutsenkoV.P., GimpilevichYu.B. Microwave radiometry of physical and biological objects. Zhitomir, Volyn’ Publ., 2003: 408. (in Russian). [11] Grubnik, B.P., Peregudov, S.N., Yanenko, A.F., et al. Application of low-temperature noise generators in practical medicine. Ukrainian Journal of Medical Engineering and Technology, 2005, 1-2: 16-23. (in Russian). [12] Ponezha G.V., Sit’ko S.P., Skripnik Yu.A., Yanenko A.F. Positive and negative flows of the microwave radiation from physical and biological objects. Physics of Alive, 1998, 6(1): 11-14. [13] Oleksiy Yanenko, Kostiantyn Shevchenko, Vladyslav Malanchuk, Оleksandra Golovchanska. Microwave Evaluation of Electromagnetic Compatibility of Dielectric Remedial and Therapeutic Materials with Human Body. International Journal of Materials Research, USA, 2019, 7(1): 37-43. [14] Spravochnik po jelektrotehnicheskim materialam. Handbook of electrical materials. Edited by Yu.V. Koritsky et al. 3rd ed., rev.. Moscow, Energoatom izdat, 1986, 1: 368. (in Russian). [15] Gabriel C. C. Dielectric Properties of Biological Tissues; Variation With Age / C. Gabriel, A. Peyman; v kn. Conn’s Handbook of Models for Human Aging (Second Edition); pod red.: Jeffrey L. Ram, P. Michael Conn. Academic Press, 2018: 1218 р. (С. 939- 952).