This PubMed-listed in vitro study tested whether 1800 MHz RF-EMF exposure can modify chemically induced DNA damage in mouse embryonic fibroblasts under standardized, non-thermal conditions. The authors report RF-EMF alone did not produce detectable DNA damage and did not significantly increase damage from hydrogen peroxide, 4-nitroquinoline-1-oxide, or cadmium. However, co-exposure with hexavalent chromium (Cr(VI)) was reported to synergistically increase DNA damage in the comet assay, which the authors interpret as possible selective exacerbation of Cr(VI)-induced genotoxicity requiring further investigation.

This RF Safe commentary argues that dismissing the National Toxicology Program (NTP) cellphone-radiation animal findings as “too high dose” is misleading because the NTP used multiple exposure tiers, including a lowest tier described as near regulatory relevance. It also claims FDA has removed webpages containing prior “safety conclusion” language while HHS has announced a new study on electromagnetic radiation and health effects, framing these as a meaningful shift in federal public-facing posture. The piece further points to the Ramazzini Institute animal study as suggesting similar tumor signals at lower exposure levels, while acknowledging animal studies alone do not establish human causation.

This animal study tested whether short-term 28 GHz (5G-band) millimeter-wave exposure modifies doxorubicin-induced cardiotoxicity in male rats and whether vitamin C mitigates effects. Co-exposure to 28 GHz EMR was reported to worsen several indices of DOX-related cardiac injury (including CAT reduction, increased BAX expression, and QT prolongation), while vitamin C provided partial attenuation. The authors emphasize that results are limited to a short-duration preclinical model and that human relevance remains preliminary.

This in vitro study tested whether 1800 MHz RF-EMF modifies chemically induced DNA damage in mouse embryonic fibroblasts under non-thermal exposure conditions. RF-EMF alone did not produce detectable DNA damage and did not significantly enhance damage from hydrogen peroxide, 4NQO, or cadmium. In contrast, co-exposure with hexavalent chromium (Cr(VI)) was reported to synergistically increase DNA damage, suggesting a selective co-genotoxic interaction under specific chemical conditions.

This animal study exposed adult male rats to 2.45 GHz electromagnetic radiation for 2 hours/day for one month and assessed testicular outcomes. The abstract reports that EMR exposure induced oxidative stress, increased inflammatory markers, and caused histological testicular injury. Alpha-lipoic acid supplementation was reported to mitigate these changes and restore several testicular proteins.

This narrative review discusses proposed non-thermal mechanisms by which chronic, low-intensity RF-EMR from ubiquitous wireless sources may affect male reproductive health. It highlights oxidative stress, mitochondrial dysfunction, impaired testosterone synthesis/steroidogenesis, and declines in sperm quality as reported outcomes. The authors argue that current SAR/thermal-based guidelines may not capture these endpoints and call for updated standards and precautionary measures.

This narrative review examines research on radiofrequency electromagnetic radiation (RF-EMR) from mobile towers and its potential association with genetic damage and genetic polymorphism in humans, with an emphasis on India. The abstract states that RF-EMR exposure may affect genetic material and suggests a link between EMR exposure and genetic damage, with possible implications for cancer risk and cell death. It also highlights that genetic polymorphisms may modify susceptibility and calls for further research to clarify health impacts.

This narrative article examines how opposing views formed regarding health and biological effects of electromagnetic radiation, focusing on ELF and RF exposures. It highlights historical controversies (e.g., childhood leukemia and ELF fields) and disputes over thermal versus non-thermal effects and reliance on SAR. The author argues that social and institutional factors, including industry influence, shaped interpretation and public discourse around EMF safety.

This case-control genetic association study in men from West Bengal, India examined variants in meiotic regulator genes (SPO11, RNF212, SYCP3) alongside reported exposure to electronic (electromagnetic) radiation as risk factors for azoospermia. It reports that genetic variants were associated with increased azoospermia risk, and that risk was higher among men aged 30+ who were also exposed to electromagnetic radiation. The authors conclude that EMF exposure may exacerbate fertility impairment in genetically predisposed men.

This conference paper uses numerical simulations to evaluate near-field exposure and thermal effects in a detailed human head model from a realistic 5G mobile phone operating at 26 GHz. The preliminary modeling suggests moderate, localized temperature increases in superficial tissues. The authors emphasize the need for higher-resolution models, refined tissue segmentation, longer exposure durations, and varied phone placements to better characterize potential impacts.

This animal experiment exposed adult male rats to 6 GHz RF-EMR (0.065 W/kg) for 4 hours/day over 42 days and compared them with sham controls. The exposed group showed higher comet assay genotoxicity metrics, though not statistically significant, and more prominent liver histopathological changes (e.g., portal inflammation and congestion). The authors conclude that 6 GHz exposure can cause histopathological and DNA-level changes in rat liver tissue under the studied conditions.

This cross-sectional study of 104 university student volunteers assessed whether mobile phone-emitted non-ionizing electromagnetic radiation is associated with changes in parotid gland-related salivary measures. The authors report higher salivary flow rate and pH with longer mobile phone usage duration, along with side-related differences in albumin, IMA, and IMAR. The paper concludes that consistent exposure to mobile phone NIER and associated heat adversely affects parotid gland function and frames this as a health risk, while calling for further long-term research.

This narrative review discusses how environmental factors may affect male reproductive health through epigenetic mechanisms, including DNA methylation, histone modifications, chromatin remodeling, and non-coding RNA regulation. It reports that electromagnetic radiation, particularly from mobile phones and wireless devices, is linked in the reviewed literature to reduced sperm count and motility, increased oxidative stress, and chromatin damage. The authors conclude there is a substantive connection between EMF exposure and adverse male reproductive outcomes and suggest practical risk-reduction guidance.

This animal study reports that dual-frequency RF EMR exposure (0.8/2.65 GHz, 4 W/kg) induced anxiety-like behavior in mice. It also reports reduced CB1R and endocannabinoid levels in the mPFC and altered endocannabinoid system markers in the BLA. CB1R overexpression or knockdown in the mPFC reportedly decreased or increased anxiety-like behavior, respectively, suggesting a mechanistic link in this model.

This animal study examined repeated pulsed-modulated RF exposure (1–4 GHz; total pulse power density 300 μW/cm2) in male and female Wistar rats and assessed behavior using the open field test. The abstract reports stress reactions and long-term memory impairment in some rats, with females described as more sensitive than males. Reported effects were transient, with behavior returning to baseline within 1.5–2 months after exposure stopped. The authors suggest potential concern for constant exposure scenarios, though this is not directly evaluated in humans here.

Moon et al. (2024) report a systematic review and meta-analysis on cellular phone RF-EMR and brain tumor risk. The abstract summary states elevated risks for three brain tumor types in analyses considering ipsilateral (same-side) phone use and reports increased risk with heavy and long-term use. The text also highlights disagreement with the 2024 WHO review and raises methodological concerns about WHO conclusions.

This rat study examined whether pulse-modulated 900 MHz and 1800 MHz RF exposure affects blood-brain barrier permeability using Evans blue dye. The abstract reports increased permeability in male rats at both frequencies (stronger at 1800 MHz) and in female rats at 900 MHz but not at 1800 MHz. The authors suggest mobile-phone-like RF exposure could increase blood-brain barrier permeability under non-thermal conditions, while noting that further mechanistic studies are needed.