ABSTRACT
With the widespread use of mobile phones, laptops, and WIFI, the effects of radio frequency radiation (RFR) on human health are of increasing concern, and there are particular concerns about its reproductive toxicity. Studies have shown that the reproductive system is a sensitive target for RFR. In males, RFR is associated with decreased sperm quality and serum testosterone levels, but there are few studies on the biological effects of RFR by altering physical parameters on the male reproductive system. This paper introduced common sources of RFR, reviewed the toxic effects and mechanisms of RFR targeting male reproductive system from the aspects of spermatogenic cells, sperm structure, blood-testicular barrier, and testicular function, and analyzed male reproductive system related toxic effects of RFR by varying physical parameters including frequency, treatment duration, and specific absorption rate, so as to provide a theoretical basis and scientific basis for the safe and reasonable use of radio frequency electromagnetic field by humans and subsequent in-depth research.
ABSTRACT
Objective:To investigate the effect of radiofrequency radiation (RF) from 5G mobile phone communication frequency bands (3.5 GHz and 4.9 GHz) on the permeability of the blood-brain barrier (BBB) in mice.Methods:A total of 24 healthy adult male C57BL/6 mice (6-8 weeks old) were randomly divided into Sham, 3.5 GHz RF and 4.9 GHz RF groups, and 8 mice in each group. Mice in the RF groups were systemically exposed to 5G cell phone radiation for consecutive 35 d(1 h/d) with 50 W/m 2 power density. The BBB permeability of mice was detected by Evans Blue (EB) fluorescence experiment. The expression levels of the BBB tight junction-related proteins (ZO-1, occludin and claudin-11) and the gap junction-related protein Connexin 43 were determined by Western blot. Results:The number of spots, fluorescence intensity and comprehensive score of EB were significantly increased in 3.5 GHz RF group and 4.9 GHz RF group compared with the Sham group ( t=12.98, 17.82, P<0.001). Compared with the Sham group, the content of S100B in mouse serum was significantly increased in 3.5 GHz RF group and 4.9 GHz RF group ( t=19.34, 14.68, P<0.001). The BBB permeability was increased in the RF group. The expression level of occludin protein was significantly reduced in the 3.5 GHz RF group ( t=-3.13, P<0.05), and this decrease was much profound in the 4.9 GHz RF group ( t=-6.55, P<0.01). But the protein levels of ZO-1, Claudin-11 and Connexin 43 in the cerebral cortex of the RF groups had no significantly difference in comparison with the Sham group( P>0.05). Conclusions:The continuous exposure of mobile phone RF at 3.5 GHz or 4.9 GHz for 35 d (1 h/d) induces an increase of BBB permeability in the mouse cerebral cortex, perhaps by reducing the expression of occludin protein.
ABSTRACT
Objective To investigate the genetic effects of radio-frequency radiation (RF-radiation) on mammalian somatic cells. Methods A meta-analysis of reported data (1991-2009) was conducted to obtain a quantitative estimate of genotoxicity ( including single-and double-strand breaks in the DNA, incidence of chromosome aberration, micronuclei, and sister chromatid exchanges) in RF-radiationexposed cells compared with sham-exposed cells or unexposed control cells. Results After RF-radiation exposure, the weighted mean difference and its 95% confidence interval was 1.03(0. 74, 1.31 )for comet tail length in radiation group, and was 0. 10 (0. 04, 0. 16) for comet tail moment compared with control group. Relative risk and its 95% confidence interval for chromosome aberration was 1.21 (0. 68, 2. 13 )for lower than 2000 MHz RF-radiation exposure group, and 1.76( 1.05, 2.97 ) for more than 2000 MHz RF-radiation exposure group. The combined relative risk and its 95% confidence interval for micronuclei formation was 1.39(1.18-1.64). The combined WMD and its 95% confidence interval for sister chromatid exchanges in radiation group was 0. 40 ( - 0. 33,1.14 ) compared with control group. Conclusions On certain RF radiation exposure conditions, it can increase in the DNA damages and micronuclei formation.There might be an increase of chromosomal aberration occurrence for RF-radiation exposure above 2000 MHz, while no significant differences for those lower than 2000 MHz RF-radiation exposure. For the incidence of sister chromatid exchanges in mammalian somatic cells, RF-radiation exposure had no significant influence.