Archive
4 postsAmeliorative Role of Coenzyme Q10 in RF Radiation-Associated Testicular and Oxidative Impairments in a 3.5-GHz Exposure Model
A rat study in Bioelectromagnetics examined GSM-modulated 3.5 GHz RF-EMF exposure (2 h/day for 30 days) and reported adverse changes in male reproductive hormones, oxidative stress markers, and testicular histology. The authors also tested Coenzyme Q10 (CoQ10) and found it partially ameliorated some RF-associated alterations. The paper notes that because the exposure used a GSM-modulated waveform, findings cannot be extrapolated to FR1 5G NR signals, and calls for further research under real-world conditions.
Ameliorative Role of Coenzyme Q10 in RF Radiation-Associated Testicular and Oxidative Impairments in a 3.5-GHz Exposure Model
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.
Development and Testing of a Novel Whole-body Exposure System for Investigative Studies of Radiofrequency Radiation in Rodents (NIEHS)
This NIEHS report describes the development and testing of a flexible whole-body radiofrequency radiation exposure system for rats and mice using updated signals relevant to wireless technologies. In 5-day studies with CDMA- and GSM-modulated signals, no visible behavioral responses were observed and comet assays reported no DNA damage in multiple tissues. The report notes technical challenges, particularly difficulty obtaining reliable body temperature measurements during exposure, and positions the system as a prototype for future mechanistic toxicology studies.
Effects of Simultaneous In-Vitro Exposure to 5G-Modulated 3.5 GHz and GSM-Modulated 1.8 GHz Radio-Frequency Electromagnetic Fields on Neuronal Network Electrical Activity and Cellular Stress in Skin Fibroblast Cells
This in-vitro study exposed primary cortical neurons and human immortalized skin fibroblasts to simultaneous 5G-modulated 3.5 GHz and GSM-modulated 1.8 GHz RF-EMF at SARs of 1 or 4 W/kg. It reports no significant changes in neuronal network firing/bursting activity and no alteration of mitochondrial ROS in fibroblasts. Stress-related signaling readouts showed only minor, threshold-level variations without a consistent pattern, and no HSF1 activation was observed. Overall, the authors conclude there is no strong evidence of biological effects under these exposure conditions.