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 animal study examined subchronic exposure to a 30 mT static magnetic field for 10 weeks in young and 36-month-old rats (n=27). The abstract reports decreased lymphocyte counts and increased NLR in both age groups, with PLR increases limited to young rats and platelet decreases reported in older rats. The authors interpret the findings as age-dependent immune/inflammation modulation, framing potential proinflammatory risk in younger animals and immunosuppressive/stress-related effects in older animals.

This animal study examined whether paternal exposure to 4.9 GHz (5G) radiofrequency radiation affects male offspring in C57BL/6 mice. It reports increased anxiety-like behavior and reduced sperm quality in adult F1 males from exposed fathers, alongside reported LRGUK hypermethylation and reduced LRGUK expression in testes. The abstract reports no significant effects on depression-like behavior, learning/memory, or fertility across F1–F2 generations.

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 animal study exposed Aedes aegypti larvae to 5G-NR RF-EMF at 3.6 GHz for 5 days under two feeding regimes. The study reports delayed development at a lower exposure level mainly in nutritionally weakened larvae, and at a higher exposure level reports developmental changes and reduced adult size attributed to dielectric heating. Mortality and wing length asymmetry were reported as unchanged, and the authors note such high exposure levels are unlikely in natural aquatic settings.

This animal study exposed male Sprague Dawley rats to 2.45 GHz Wi-Fi for varying daily durations over eight weeks and assessed reproductive hormones and LHCGR expression. Serum LH and testosterone did not differ significantly from controls, but LHCGR mRNA increased with longer exposure and LHCGR protein showed decreases with shorter exposures with partial improvement at 24 hours/day. The findings suggest molecular alterations in testicular tissue despite stable systemic hormone levels.

This animal study examined Wi-Fi RF-EMR exposure in adult zebrafish (4 hours/day for 30 days) and assessed reproductive tissues and offspring outcomes. The abstract reports testicular and ovarian histopathological abnormalities in exposed adults. Offspring from exposed parents, maintained under EMF-free conditions, reportedly showed increased mortality, morphological abnormalities, and anxiety-like behavior, with malformations increasing with longer parental exposure.

This animal study used Drosophila knockout lines to examine whether visual (Rh1) versus non-visual (Rh7) opsins contribute to blue-light-associated neural damage. Flies were continuously exposed to 488 nm blue light from egg deposition to 20 days, and brain DNA damage and vacuolisation were assessed. The study reports greater DNA damage and neurodegeneration markers in Rh1 knockout flies than in wild-type or Rh7 knockout flies, and concludes Rh1 is a predominant mediator of blue-light-induced neurotoxicity in the fly CNS.

This animal study examined whether prenatal exposure to 3.5 GHz radiofrequency radiation (2 hours/day) affects male reproductive outcomes later in life. Male rat offspring assessed at 12 months showed multiple adverse testicular and cellular findings in exposed groups versus sham controls, including impaired spermatogenesis markers, increased abnormal sperm morphology, increased DNA damage, and increased apoptosis, with full-gestation exposure generally most pronounced. The authors interpret the results as evidence of persistent reproductive toxicity from prenatal exposure and call for further mechanistic work and precautionary actions.

This animal study used metabolomics to assess metabolic changes in male Drosophila melanogaster exposed to 3.5 GHz RF-EMF at 0.1, 1, and 10 W/m². It reports disruptions in four metabolic pathways and 34 differential metabolites, with significant decreases in several metabolites including GABA, glucose-6-phosphate, and AMP. The authors interpret the findings as suggesting RF-EMF-related metabolic disturbance, while noting no clear dose-dependent pattern.

This randomized controlled animal study examined chronic 35.5 GHz millimeter wave exposure in male Wistar rats (2 hours/day for 60 days) compared with control and sham groups. The exposed group showed reduced sperm count and viability along with testicular histopathological changes. Oxidative stress markers shifted toward increased lipid peroxidation and reduced antioxidant defenses, and comet assay results indicated increased DNA damage.

This animal study exposed zebrafish embryos to static electromagnetic fields for 63 days post-hatching across aquariums positioned 30–99 cm from the source, with an EMF-free control. The abstract reports strong shifts in sex distribution (including 100% female at the closest distance), markedly reduced survival in exposed groups, and histological liver and gonadal damage. The authors frame the findings as evidence of potential ecological risk via disrupted sex ratios and compromised health.

This animal study exposed mice to 2.45 GHz electromagnetic fields daily for up to 5 months and assessed liver effects using serum tests, lipidomics, histology, and single-cell/spatiotemporal transcriptomics. The authors report that hepatic cell types differed in sensitivity, with hepatocytes, endothelial cells, and monocytes showing notable transcriptomic disruptions. Reported changes involved lipid metabolism and immune regulation and were spatially enriched in peri-portal liver regions. The authors frame the findings as evidence of significant biological impacts on the liver from long-term EMF exposure.

This animal study exposed rats to Wi‑Fi waves for 7 hours/day for 2 months and assessed sperm parameters, serum testosterone, and testicular/epididymal pathology, with and without coenzyme Q10 (CoQ10). The authors report that Wi‑Fi exposure was linked to worse sperm parameters, lower testosterone, and adverse testicular pathology. CoQ10 supplementation during exposure was reported to mitigate these changes compared with Wi‑Fi exposure alone.

This animal study exposed adult zebrafish to 2.45 GHz Wi‑Fi radiation for 4 hours daily over 30 consecutive days. The authors report neurobehavioral impairments with altered locomotion, alongside decreased acetylcholinesterase and increased brain oxidative stress. They conclude these findings indicate a safety risk and call for further mechanistic and public health research.

This animal study examined thyroid histomorphometry in juvenile male Wistar rats after 2 weeks of 5G EMF exposure (3.5 GHz, 1.5 V/m). Exposed rats showed larger follicle and colloid areas and a significantly lower Thyroid Activation Index, which the authors interpret as thyroid hypoactivity. The authors suggest this may represent a potential health risk and call for further work including hormone assays and mechanistic studies.

This animal study examined 2100 MHz radiofrequency radiation exposure effects on auditory brainstem responses and brain oxidative/ultrastructural markers in adult rats. The 1-week exposure group showed prolonged ABR latencies and biochemical/structural changes consistent with oxidative stress and cellular injury. The authors report no harmful effects in the 10-week exposure condition with rest days under the studied protocol.

This animal study measured core body temperature in free-moving male and female Sprague Dawley rats during and after 3-hour exposure to 1.95 GHz RF-EMF at multiple whole-body average SAR levels. A measurable thermal response was reported at 4 W/kg, while lower SAR conditions showed smaller or no significant temperature increases. The authors note that temperature dropped quickly after exposure ended, implying post-exposure measurements may underestimate peak heating.

This animal study examined continual 2.4 GHz Wi‑Fi exposure (200–500 μW/m²) during 9 days of chicken embryo incubation and assessed the mesonephros at day 9. The authors report no adverse effects on general mesonephros development, but describe moderate degenerative changes and vascular congestion without inflammatory infiltrate. They also report significantly increased apoptotic and proliferating cells and up-regulation of caspase‑1 gene expression, interpreted as disruption of regulatory processes during development.

This animal study exposed Sprague-Dawley rats (including pregnant females and offspring) to 2.45 GHz Wi-Fi or mobile jammer radiation for 2 hours daily over two weeks and assessed thyroid hormones and thyroid histology. The abstract reports significant changes in T4 in exposed adult males and significant differences in T3 among male offspring exposed to jammer radiation. Histopathology reportedly showed disrupted thyroid follicular structure in exposed rats. The authors conclude these findings support a potential link between non-ionizing radiation exposure and altered thyroid endocrine and histological parameters.

This animal study exposed rats to a 1800 MHz electromagnetic field for 12 weeks and assessed hormones, sperm quality, and behavior. The abstract reports increased corticosterone, decreased thyroid-stimulating hormone, reduced sperm motility/viability, and increased anxiety-like behavior in exposed rats. Some hormonal changes reportedly persisted for at least 2 weeks after exposure ended, and the authors frame the results as indicating adverse endocrine, reproductive, and behavioral effects.