№ 1 / 2016 / 48-54

Problems of investigations in sphere of electromagnetic fields impact on biological objects

Author: Busygina A.V.¹, Komnatnov M.E.², Matveyenko O.A.³

Abstract

Problems of the investigations in the sphere of electromagnetic fields impact on biological objects in the TEM-cell have been considered. Researches on biological objects exposed to electromagnetic fields (cell cultures, plants, worms, insects, animals) have been systematized. Features of devices for climatic (temperature, humidity, CO₂ and nutrients) and electromagnetic exposure needed for research of specific biological objects have been described. The need for temperature control and video monitoring during the research on biological objects exposed to electromagnetic fields has been justified. The results presented may be useful for development of research methods for investigation of the electromagnetic fields impact on specific biological objects, as well as for the development of technical requirements in order to provide devices useful for such studies.

Key words

TEM-cell, biological objects, electromagnetic fields

References

1. Ardoino L., Lopresto V., Mancini S. et al. A radio-frequency system for in vivo pilot experiments aimed at the studies on biological effects of electromagnetic fields // Phys. Med. Biol. 2005. 50. (15). 3643–3654.

2. Baan R., Grosse Y., Lauby-Secretan B. et al. Carcinogenicity of radiofrequency electromagnetic fields // Lancet Oncol. 2011. 12. (7). 624–626.

3. Crawford M.L. Generation of standard EM fields using TEM transmission cells // IEEE Trans. Electromagn. Compatibility. 1974. EMC-16. 189–195.

4. De Pomerai D., Daniells C., David H. et al. Microwave radiation induces a heat-shock response and enhances growth in the nematode Caenorhabditis elegans // IEEE Trans. Microw. Theory Techn. 2000. 48. 2076–2081.

5. Diem E., Schwarz C., Adlkofer F. et al. Non-thermal DNA breakage by mobile-phone radiation (1800 MHz) in human fibroblasts and in transformed GFSH-R17 rat granulosa cells in vitro // Mutat. Res. 2005. 583. (2). 178–183.

6. Ganatara V., Yadav K., Senjaliya C. et al. Health hazards due to electromagnetic radiation in the workplace // Int. J. Innov. Res. Sci. Technol. 2015. 1. (8). 138–145.

7. Gatta L., Pinto R., Ubaldi V. et al. Effects of in vivo exposure to GSM-modulated 900 MHz radiation on mouse peripheral lymphocytes // Radiat. Res. 2003. 160. (5). 600–605.

8. Jarrige P., Ticaud N., Kohler S. et al. Electrooptic probe adapted for bioelectromagnetic experimental investigations // IEEE Trans. Instrum. Meas. 2012. 61. (7). 2051–2058.

9. Kohler S., O’Connor R.P., Vu T.D.T. et al. Experimental microdosimetry techniques for biological cells exposed to nanosecond pulsed electric fields using microﬂuorimetry // IEEE Trans. Microw. Theory Techn. 2013. 61. (5). 2015–2022.

10. Komnatnov M.E., Busygina A.V. Module for visual control of in vitro results of the joint impact of climatic and electromagnetic factors on living tissue // EDM: Proc. 16th Int. conf. Erlagol, 2015. 576–579.

11. Komnatnov M.E., Gazizov T.R. Environmental shielded TEM chamber for biomedical testing // IMWS-BIO: Proc. IEEE MTT-S Int. Microwave Workshop Series. London, 2014. 1–4.

12. Komnatnov M.E., Gazizov T.R. Chamber for joint environmental and electromagetic testing of electronic components // Tekhnika radiocvyazi = Technology of Radio Communication. 2014. 23. (3). 84–91. [In Russian].

13. Komnatnov M.E., Gazizov T.R. On joint climatic and electromagetic testing of radioelectronic equipment // Doklady Tomskogo gosudarstvennogo universiteta sistem upravleniya i radioelektroniki = Proceedings of Tomsk State University of Control Systems and Radioelectronics. 2014. 34. (4). 39–45. [In Russian].

14. Kwee S., Raskmark P. Changes in cell proliferation due to environmental non-ionizing radiation 1. ELF electromagnetic fields // Bioelectrochem. Bioenerg. 1995. 36. (2). 109–114.

15. Kwee S., Raskmark P. Changes in cell proliferation due to environmental non-ionizing radiation 2. Microwave radiation // Bioelectrochem. Bioenerg. 1998. 44. (2). 251–255.

16. Kwee S., Raskmark P., Velizarov S. Changes in cellular proteins due to environmental non-ionizing radiation. I. Heat-shock proteins // Electromagn. Biol. Med. 2001. 20. (2). 141–152.

17. Lallechere S., Girard S., Roux D. et al. Mode stirred reverberation chamber (MSRC): a large and efficient tool tolead high frequency bioelectromagnetic in vitro experimentation // Prog. Electromagn. Res. B. 2010. 26. 257–290.

18. Lim H.B., Cook G.G., Barker A.T., Coulton L.A. Effect of 900 MHz electromagnetic fields on nonthermal induction of heat-shock proteins in human leukocytes // Radiat. Res. 2005. 163. (1). 45–52.

19. Linz K.W., von Westphalen C., Streckert J. et al. Membrane potential and currents of isolated heart muscle cells exposed to pulsed radio frequency fields // Bioelectromagnetics. 1999. 20. (8). 497–511.

20. Malaric K., Tkalec M., Bartolic J. Use of GTEM-Cell in Biomedical Experiments // TEMI-2001: Proc. 11th IMEKO TC-4 Symposium, 2001. 394–396.

21. Martens L., Van Hese J., De Zutter D. et al. Electromagnetic field calculations used for exposure experiments on small animals in TEM-cells // Bioelectrochem.Bioenerg. 1993. 30. 73–81.

22. Merla C., Ticaud N., Arnaud-Cormos D. et al. Real-time RF exposure setup based on a multiple electrode array (MEA) for electrophysiological recording of neuronal networks // IEEE Trans. Microw. Theory Techn. 2011. 59. (3). 755–762.

23. Panagopoulos D.J., Karabarbounis A., Margaritis L.H. Effect of GSM 900-MHz mobile phone radiation on the reproductive capacity of Drosophila melanogaster // Electromagn. Biol. Med. 2015. 23. (1). 29–43.

24. Salovarda M., Malaric K. Use of GTEM-cell and wire patch cell in calculating thermal and non-thermal biological effects of electromagnetic fields // Advanced Microwave and Millimeter Wave Technologies Semiconductor Devices Circuits and Systems. Ed. M. Mukherjee, 2010. Doi: 10.5772/8748.

25. Savost’yanik S.A., Spas V.V., Yakubtsevich R.E. et al. Magnetic fields and modern medicine // Meditsinskie novosti = Medicinal news. 2010 (12). 11–18. [In Belorussian].

26. Schuderer J., Samaras T., Oesch W. et al. High Peak SAR Exposure Unit With Tight Exposure and Environmental Control for In Vitro Experiments at 1800 MHz // IEEE Trans. Microw. Theory Techn. 2004. 52. (8). 2057–2066.

27. Teodori L., Grabarek J., Smolewski P. et al. Exposure of cells to static magnetic field accelerates loss of integrity of plasma membrane during apoptosis // Cytometry. 2002. 49. (3). 113–118.

28. Ticaud N., Kohler S., Jarrige P. et al. Specific absorption rate assessment using simultaneous electric field and temperature measurements // IEEE Antennas Waireless Propag. Lett. 2012. 11. 252–255.

29. Velizarov S., Raskmark P., Kwee S. The effects of radiofrequency fields on cell proliferation are non-thermal // Bioelectrochem. Bioenerg. 1999. 48. (1). 177–180.

30. Zhao W., Yang R. Experimental study on conformational changes of lysozyme in solution induced by pulsed electric field and thermal stresses // J. Phys. Chem. B. 2010. 114. (1). 503–510.

About Authors (Correspondence):

Busygina A.V. – postgraduate student of department of television and control, е-mail: bav-tusur@mail.ru

Komnatnov M.E. – junior researcher of scientific research laboratory of safety electromagnetic compatibility,е-mail: maxmek@mail.ru

Matveyenko O.A. – candidate of biological sciences, researcher of scientific research laboratory of safety electro–magnetic compatibility, е-mail: alterra@inbox.ru

Full Text

8-1-2016.pdf

Received: 22/03/2016

Accepted: 02/01/1970