This in vitro study examined strictly non-thermal, GSM-like 3.5 GHz RF-EMF exposure in cultured mouse dorsal root ganglion neurons for 1–24 hours. The authors report time-dependent reductions in cell viability alongside increased ROS and changes consistent with mitochondria-mediated apoptosis (e.g., Bax/caspase-3 up, cytochrome c release, Bcl-2 down) and increased p75NTR. They conclude these findings provide mechanistic evidence of peripheral neuronal vulnerability to mid-band RF exposure and call for further in vivo research.

This review summarizes studies reporting radiofrequency radiation (RFR)-associated changes in gene expression across biological systems. Reported affected genes relate to cellular stress responses, oxidative processes, apoptosis, DNA damage detection/repair, protein repair, and neural function regulation. The authors highlight reported gene expression effects at or below 0.4 W/kg SAR and argue this challenges current guideline assumptions, while noting that not all studies find significant effects.

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 rat study tested whether 2600 MHz radiofrequency field exposure interacts with indomethacin to affect gastric tissue. Both exposures alone were reported to increase oxidative stress and reduce antioxidant markers in the stomach. Co-exposure was reported to intensify oxidative stress, apoptosis, and histological gastric mucosal injury compared with either factor alone, consistent with a synergistic detrimental effect in this model.

This rat study examined 60-day RF-EMF exposure at 3.5 GHz and 24 GHz for 1 or 7 hours per day and assessed testicular cytokines, apoptosis-related gene expression, and sperm quality. The authors report changes consistent with altered immune signaling and pro-apoptotic pathways, alongside reduced sperm parameters (frequency- and duration-dependent). The conclusion frames these findings as an EMF safety concern and suggests longer daily exposure worsened negative effects.

This rat study assessed whether alpha-lipoic acid (ALA) modifies liver effects from extremely low-frequency magnetic field (ELF-MF) exposure. ELF-MF exposure (2 mT, 4 hours/day for 30 days) was associated with increased liver pathology and higher apoptosis markers (TUNEL, caspase-3) compared with other groups. ALA reduced several histopathological changes and lowered TUNEL/caspase-3, but did not improve fibrosis or biliary proliferation.

This animal and in vitro study examined non-thermal 900 MHz RF-EMF exposure during prenatal and postnatal development at 0.08 and 0.4 W/kg SAR. The authors report changes consistent with altered neurodevelopment, including reduced BDNF, reduced in vivo cell proliferation, and disrupted synaptic balance in rat pup brain regions. In vitro, exposed neural stem cells showed increased apoptosis and DNA double-strand breaks and shifts in cell populations toward glial lineages. The authors conclude that regulatory-level 900 MHz exposure can disrupt key neurodevelopmental processes in rodents.

This mouse study examined whether cell phone radiation affects T lymphocytes over 2–8 weeks of exposure. CD4 and CD8 subset percentages were similar across groups, but after more than six weeks, exposed groups showed increased T-cell apoptosis and reduced transformation rates compared with shams. The study also reports decreased IL-10 and increased IL-12 in exposed groups, suggesting time-dependent immunological changes under the tested conditions.

This in vitro study exposed BV2 mouse microglial cells to 3.5 GHz EMF for 2 hours and reports reduced cell growth and increased apoptosis alongside oxidative stress and signaling changes. The authors report that ROS generation and activation of JNK-1/2 and p38 MAPK were key events in the observed cytotoxicity. Polydeoxyribonucleotide (PDRN) reportedly reduced several EMF-associated cytotoxicity markers, suggesting a potential mitigating effect under the tested conditions.

This review discusses potential impacts of radiofrequency electromagnetic fields from technologies such as Wi‑Fi and mobile phones on the central nervous system, neurotransmitter dynamics, and reproductive health. It describes proposed mechanisms including oxidative stress, thermal effects, altered neurotransmitter activity, ion channel changes, and neuronal apoptosis, while acknowledging conflicting evidence. The authors note that Wi‑Fi RF exposure has not been confirmed to exceed safety guidelines but argue that updated standards and long-term studies are needed, particularly for children/adolescents and in the context of expanding technologies such as 5G.

This animal study examined maternal mobile phone exposure during different gestational windows in Wistar rats and assessed ovarian development and hormones in neonatal offspring. Compared with sham (phone off), exposed groups (standby and conversation/standby) were reported to have lower neonatal estrogen and progesterone and reduced primordial follicle/primary oocyte measures, with stronger effects after longer exposure. The study also reports increased primordial follicle apoptosis, particularly in the conversation/standby condition, and notes effects even with first-week gestational exposure.

This animal study exposed male Wistar rats to 900 MHz RF-EMR from a mobile phone for 1 hour daily over four weeks and assessed behavior and tissue changes. The authors report altered contextual fear conditioning-related behavior in exposed rats. Histological assessments indicated apoptosis and enlarged perivascular space in the hippocampal CA3 region and apoptotic/inflammatory-like changes in the adrenal zona fasciculata, with no reported differences in adrenal medulla cytoarchitecture.

This animal study exposed chick embryos to electromagnetic waves from a mobile phone and compared them with unexposed controls. Electron microscopy on days 10 and 15 reported neuronal and cerebellar cellular alterations in the exposed group, including features described as apoptosis and mitochondrial swelling. The authors also report compromised blood-brain barrier integrity and conclude the exposure adversely affects brain development.