This animal experiment assessed GSM-modulated 3.5 GHz RF exposure in male Wistar rats and reported hormonal, oxidative, and histological changes consistent with testicular impairment. RF exposure was associated with lower testosterone, LH, and FSH, higher oxidative stress (increased MDA and TOS), and degenerative testicular histology. Coenzyme Q10 supplementation partially mitigated several reported changes. The authors caution against generalizing these results to FR1 5G NR signals and call for further research.

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 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 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 occupational epidemiology study used machine learning to evaluate whether workplace exposures (including magnetic and electric fields, vibration, noise, and heat stress) predict male reproductive indicators in 80 workers. The models and explainable AI outputs highlighted magnetic and electric field exposures and age as key predictors linked to lower free testosterone. The authors also report a 10-year forecast identifying electric field exposure as the most important long-term risk factor.

This animal study examined short- and long-term 700 MHz (lower-band 5G) radiofrequency exposure in female Wistar rats, comparing control, sham, and exposed groups. It reports no DNA damage and no change in estrous cycle length, but increased ovarian oxidative stress markers in exposed animals. Long-term exposure was associated with ovarian histopathological alterations, while estradiol and progesterone stayed within normal ranges and testosterone increased slightly but significantly.