This exposure assessment measured outdoor micro-environment RF-EMF levels in daily-life settings across urban and suburban locations in Japan using a portable device (50 MHz–6 GHz) with GPS. Reported exposure levels were higher in urban areas, with railway stations showing the highest levels among the environments measured. The authors emphasize the need for further comprehensive studies and frame prolonged RF-EMF exposure as an ongoing public health concern.

This study reports measurements of electric field intensity (E) and magnetic flux density (B) from electric vehicles (inside driver/passenger seats during driving) and EV supply equipment (near chargers during charging) up to 400 kHz in and around Chennai. E and B inside EVs and E around EVSEs were reported to be within ICNIRP/IEEE guideline limits. However, B around certain EVSE positions reportedly exceeded a general public threshold (~200 T), and a preliminary FEM analysis suggested relatively higher fields at charging infrastructure. The authors call for further research on long-term health impacts and recommend policy actions to mitigate exposure.

RF Safe argues that a potential MrBeast-branded mobile service (“Beast Mobile”) could drive high adoption among children and therefore raises ethical concerns about children’s exposure to radiofrequency (RF) emissions from always-on, body-worn devices. The post claims the scientific and legal context has shifted and contends that relying on existing regulatory compliance is insufficient, urging a “LiFi compatibility plan” as an exposure-reduction alternative. It cites modeling literature about potentially higher localized absorption in children and references a 2025 systematic review it says found increased cancer incidence in RF-exposed experimental animals, while framing the overall situation as negligence if child-focused marketing proceeds without additional safeguards.

An RF Safe commentary argues that radiofrequency emissions from cell towers should be treated as a “physical invasion” of private property under the U.S. Constitution’s Fifth Amendment Takings Clause. The author claims courts and agencies have misframed RF exposure as a regulatory issue rather than a per se physical occupation, citing Supreme Court takings precedents (e.g., Loretto and Cedar Point). The piece also asserts that federal law (referencing Section 704) limits objections on health grounds, strengthening the need for a takings-based legal theory.

RF Safe promotes its QuantaCase™ (also called TruthCase™) as the “best anti-radiation phone case,” citing a review of 2025 market options, expert analyses, and user feedback from platforms like Reddit and Amazon. The post argues that while no case provides 100% protection, QuantaCase’s approach is more credible than “fake” anti-radiation cases and should be paired with exposure-reduction behaviors (e.g., distance and wired tech). It also references a claimed WHO 2025 position on animal cancer certainty, but provides no verifiable details in the excerpt.

This PubMed-listed article argues that ambient nonionizing EMF exposures (especially RF-EMF) have increased substantially over the past 60 years and are now pervasive, including from terrestrial networks and low-earth-orbit satellites. It claims these chronic, low-intensity exposures are biologically active and may disrupt critical functions in nonhuman species that rely on geomagnetic cues. The paper discusses nonhuman physiologies and proposes public policy recommendations for wildlife protection, including mitigation and creation of EMF-reduced zones during sensitive periods such as migration and breeding.

RF Safe argues that current RF-EMF exposure standards are overly focused on thermal effects and should be replaced with a “post-thermal” regulatory paradigm that accounts for claimed non-thermal biological impacts. The piece cites a mix of mechanistic hypotheses, animal studies, epidemiology, and legal/policy developments (e.g., the 2021 D.C. Circuit EHT v. FCC decision) to support a precautionary reform agenda. It also asserts that recent WHO work in 2025 strengthens the case for tumor-related risks, though these characterizations are presented as the author’s interpretation rather than independently verified within the feed item.

RF Safe publishes a mechanistic white-paper-style post arguing that pulsed/low-frequency components of RF exposure could introduce “phase noise” into voltage-gated ion channel (VGIC) voltage sensors (S4), degrading the timing of membrane potentials and calcium (Ca²⁺) oscillations that immune cells use for activation and tolerance decisions. The post claims such timing disruption could mis-set immune thresholds, promote inflammation, and trigger mitochondrial ROS and mtDNA release that sustains a feed-forward inflammatory loop. It frames reported tumor patterns in animal bioassays (e.g., cardiac schwannomas, gliomas) as consistent with this proposed “timing-fidelity” mechanism, while acknowledging competing views on whether RF at current limits can couple to VGICs.

RF Safe presents a mechanistic hypothesis that low-frequency electromagnetic fields (LF-EMFs) can disrupt the timing (“fidelity”) of voltage-gated ion channel activity, creating bioelectric “phase noise” that could alter calcium signaling and gene transcription involved in immune function. The article further argues that this mistiming may impair mitochondrial function, increasing reactive oxygen species and inflammatory feedback loops, potentially contributing to immune dysregulation. It also proposes a policy/engineering response focused on reducing indoor RF exposure and promoting alternatives such as LiFi, while citing animal and epidemiology findings as suggestive but not definitive support for the broader framework.

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.

The review states there is no scientific consensus on whether Wi‑Fi (2.4/5 GHz) contributes to Alzheimer's disease through oxidative stress, and that existing results are mixed and inconclusive. It discusses an indirect analysis linking oxidative-stress-responsive genes after 2.4 GHz exposure with genes associated with Alzheimer's disease. The authors suggest chronic exposure could affect regulation of neurodegeneration-related genes (e.g., GSK3B, APOE), while emphasizing that a direct relationship has not been demonstrated and more research is needed.

This cross-sectional questionnaire study surveyed 355 Polish physicians about EMF health effects and electromagnetic hypersensitivity (EHS). Physicians reported limited knowledge and low familiarity with WHO guidance for managing people who believe they are hypersensitive to EMF, though most were willing to learn more. Many physicians reported encountering patients attributing symptoms to EMF, which the authors frame as highlighting a need for improved physician education and reliable public information.

This dosimetric study evaluated whether existing EM safety guidelines protect individuals with conductive implants by assessing implant-related local field enhancements. Across 10 kHz to 1 GHz, the authors report large increases in psSAR10mg and local electric fields near implants, particularly below 100 MHz. In human anatomical models with implants exposed to an 85 kHz wireless power transfer coil and a 450 MHz dipole, the study reports guideline exceedances and elevated psSAR10mg, while the modeled temperature rise at 450 MHz remained under 0.4 K after six minutes. The authors conclude current guidelines are insufficient for people with implants and propose regulatory changes.

This paper presents a bibliometric analysis of Web of Science literature (2012–2025) on potential health effects related to 5G antennas. It reports a marked increase in publications in the past five years, with substantial attention to dosimetric metrics (SAR and power density) and their regulatory limits. The authors forecast continued growth in the field and emphasize the need for ongoing research and interdisciplinary collaboration focused on potential health risks and compliance.

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.