Changes in cell proliferation due to environmental non-ionizing radiation: 2. Microwave radiation

Abstract Due to the use of mobile telephones, there is an increased exposure of the environment to weak radiofrequency (RF) electromagnetic fields, emitted by these devices. This study was undertaken to investigate if the microwave radiation from these fields will have a similar effect on cell proliferation as weak electromagnetic (ELF) fields. The field was generated by signal simulation of the Global System for Mobile communications (GSM) of 960 MHz. Cell cultures, growing in microtiter plates, were exposed in a specially constructed chamber, a Transverse Electromagnetic (TEM) cell. The Specific Absorption Rate (SAR) values for each cell well were calculated for this exposure system. Experiments were performed on cell cultures of transformed human epithelial amnion cells (AMA), which were exposed to 960 MHz microwave fields at three different power levels and three different exposure times, respectively. It was found that cell growth in the exposed cells was decreased in comparison to that in the control and sham exposed cells. Cell proliferation during the period following exposure varied not only with the various SAR levels, but also with the length of exposure time. On the other hand, repeated periods of exposure did not seem to change the effects. There was a general linear correlation between power level and growth change. However, the exposure time required to obtain the maximum effect was not the same for the various power levels. It turned out that at low power level, a maximum effect was first reached after a longer exposure time than at higher power level. A similar phenomenon was registered in the studies on ELF electromagnetic fields. Here, it was found that there was a linear correlation between the length of exposure time to obtain maximum effect and field strength.

[1]  H. Lai,et al.  Acute low-intensity microwave exposure increases DNA single-strand breaks in rat brain cells. , 1995, Bioelectromagnetics.

[2]  D. Lange,et al.  Modification of membrane fluidity in melanin-containing cells by low-level microwave radiation. , 1992, Bioelectromagnetics.

[3]  P. Czerski,et al.  Effects of continuous and pulsed 2450-MHz radiation on spontaneous lymphoblastoid transformation of human lymphocytes in vitro. , 1992, Bioelectromagnetics.

[4]  P. Raskmark,et al.  Changes in cell proliferation due to environmental non-ionizing radiation 1. ELF electromagnetic fields , 1995 .

[5]  C. Gandhi,et al.  Microwave induced stimulation of32Pi incorporation into phosphoinositides of rat brain synaptosomes , 1989, Radiation and environmental biophysics.

[6]  S. Cleary,et al.  Glioma proliferation modulated in vitro by isothermal radiofrequency radiation exposure. , 1990, Radiation research.

[7]  W. Grundler Intensity- and frequency-dependent effects of microwaves on cell growth rates , 1992 .

[8]  T. Mosmann Rapid colorimetric assay for cellular growth and survival: application to proliferation and cytotoxicity assays. , 1983, Journal of immunological methods.

[9]  R. Shore Electromagnetic radiations and cancer cause and prevention , 1988, Cancer.

[10]  T. Litovitz,et al.  The role of coherence time in the effect of microwaves on ornithine decarboxylase activity. , 1993, Bioelectromagnetics.

[11]  D. Lange,et al.  Japanese encephalitis virus (JEV): potentiation of lethality in mice by microwave radiation. , 1991, Bioelectromagnetics.

[12]  A Basten,et al.  Lymphomas in E mu-Pim1 transgenic mice exposed to pulsed 900 MHZ electromagnetic fields. , 1997, Radiation research.

[13]  E. Balcer-Kubiczek,et al.  Neoplastic transformation of C3H/10T1/2 cells following exposure to 120-Hz modulated 2.45-GHz microwaves and phorbol ester tumor promoter. , 1991, Radiation research.

[14]  Stephen F. Cleary,et al.  EFFECTS OF ISOTHERMAL 2.45 GHZ MICROWAVE RADIATION ON THE MAMMALIAN CELL CYCLE : COMPARISON WITH EFFECTS OF ISOTHERMAL 27 MHZ RADIOFREQUENCY RADIATION EXPOSURE , 1996 .

[15]  J. Parker,et al.  Effect of radiofrequency radiation on mRNA expression in cultured rodent cells. , 1988, Physiological chemistry and physics and medical NMR.

[16]  H. Fröhlich,et al.  Biological coherence and response to external stimuli , 1988 .

[17]  V. Garaj-Vrhovac,et al.  The correlation between the frequency of micronuclei and specific chromosome aberrations in human lymphocytes exposed to microwave radiation in vitro. , 1992, Mutation research.

[18]  H. Brown,et al.  Ouabain inhibition of kidney ATPase is altered by 9.14 GHz radiation. , 1991, Bioelectromagnetics.

[19]  S. Dutta,et al.  Intensity dependence of enolase activity by modulated radiofrequency radiation , 1992 .

[20]  D. Eichler Nearly closed loops in biological systems as electromagnetic receptors , 1997 .

[21]  E. Kovács,et al.  Time course of the interaction of low level 2.45 GHz radiation with the erythrocyte membrane , 1996 .

[22]  Henry Lai,et al.  Neurological Effects of Radiofrequency Electromagnetic Radiation , 1994 .

[23]  C. Blackman,et al.  Dose dependence of acetylcholinesterase activity in neuroblastoma cells exposed to modulated radio-frequency electromagnetic radiation. , 1992, Bioelectromagnetics.

[24]  W F Pickard,et al.  Measurement of DNA damage after exposure to electromagnetic radiation in the cellular phone communication frequency band (835.62 and 847.74 MHz). , 1997, Radiation research.