Martínez MA, Úbeda A, Moreno J, Trillo MÁ · 2016
Researchers exposed human brain tumor cells (neuroblastoma) to 50 Hz magnetic fields at 100 microtesla - similar to levels near power lines - for various time periods. The magnetic field exposure triggered specific cellular pathways that increased cell proliferation, with the effects appearing to be mediated by reactive oxygen species (free radicals). This suggests that power frequency magnetic fields can stimulate abnormal cell growth through oxidative stress mechanisms.
Yin C, Luo X, Duan Y, Duan W, Zhang H, He Y, Sun G, Sun X · 2016
Researchers exposed rat brain cells to 50 Hz magnetic fields and found significant damage including cell death and DNA harm. However, natural compounds from lotus seed pods prevented most of this damage, suggesting magnetic fields can harm brain cells but certain antioxidants may offer protection.
Ansari AM et al. · 2016
Researchers exposed mice to extremely low frequency magnetic fields (the type emitted by power lines and electrical devices) for either 2 hours once or 2 hours daily for 2 weeks. They found that long-term exposure reduced depression-like behavior in the mice, while short-term exposure interfered with antidepressant medications. This suggests that chronic EMF exposure may alter brain chemistry and affect how psychiatric medications work.
Ma Q et al. · 2016
Researchers exposed embryonic brain stem cells to 50 Hz electromagnetic fields from power lines and electrical devices. The EMF exposure significantly enhanced the cells' development into neurons and promoted growth of neural connections. This suggests electromagnetic fields could influence brain formation during early development.
Madjid Ansari A et al. · 2016
Researchers exposed mice to extremely low frequency magnetic fields (the type generated by power lines and electrical appliances) to study effects on depression-like behavior. They found that short-term exposure (2 hours) had no effect, but long-term exposure (2 hours daily for 2 weeks) actually reduced depressive symptoms in the mice. The study suggests this effect may work through changes in nitric oxide levels in the brain.
Maes A, Anthonissen R, Wambacq S, Simons K, Verschaeve L. · 2016
Scientists exposed cells to 50 Hz magnetic fields from power lines at levels above 50 microtesla and found genetic damage patterns similar to Alzheimer's patients. The exposure caused chromosome instability in cells, suggesting a possible biological link between power line magnetic fields and Alzheimer's disease development.
Shahbazi-Gahrouei D, Shiri L, Alaei H, Naghdi N. · 2016
Researchers exposed rats to 10 Hz magnetic fields for 15 days to study brain chemistry effects. Three hours of daily exposure decreased serotonin breakdown products in the brain's mood-regulating region, while one hour had no effect. This suggests magnetic fields can alter brain chemistry linked to mood.
Rostami A et al. · 2016
Researchers exposed male rats to extremely low frequency electromagnetic fields (ELF-EMF) at 3 Hz and 60 Hz for several days and measured effects on brain activity and behavior. They found that both frequencies significantly reduced the rats' movement and decreased the firing rate of neurons in the locus coeruleus, a brain region important for arousal and attention. The study also detected widespread changes in brain proteins, suggesting that ELF-EMF exposure can alter brain function at multiple biological levels.
Reale M et al. · 2016
Researchers exposed human brain cells to extremely low frequency electromagnetic fields (the type from power lines) for up to 48 hours to see if it would cause neurological damage. They found no significant harmful effects on the cells' ability to manage oxidative stress or inflammation, though there were minor changes in serotonin metabolism. The study suggests that ELF-EMF exposure at these levels is unlikely to contribute to neurodegenerative diseases.
Ghosn R et al. · 2015
Researchers exposed 26 healthy young adults to radiofrequency signals from a mobile phone while measuring their brain activity using EEG (electroencephalogram). They found that RF exposure significantly reduced alpha brain waves (8-12 Hz), which are associated with relaxed, alert states, and this effect persisted even after the exposure ended. The study carefully controlled for other factors like stress hormones and caffeine that could influence brain activity.
Benassi B et al. · 2015
Researchers exposed human brain cells to 50 Hz magnetic fields (the same frequency as power lines) and found that while the fields didn't harm the cells directly, they made the cells much more vulnerable to a chemical toxin that causes Parkinson's disease-like damage. The magnetic field exposure disrupted the cells' natural antioxidant defenses, causing normally survivable toxin levels to trigger cell death through oxidative stress.
Zhang Y, Liu X, Zhang J, Li N. · 2015
Researchers exposed rats to extremely low frequency electromagnetic fields (the type emitted by power lines and electrical devices) for 12 weeks to see if it would affect memory and brain health, particularly markers associated with Alzheimer's disease. They found no changes in the rats' memory performance, brain tissue structure, or levels of amyloid-beta proteins that are linked to Alzheimer's. This suggests that short-term exposure to these fields at the levels tested did not harm cognitive function in this animal model.
Yang ML, Ye ZM · 2015
Researchers exposed bone cancer cells to extremely low frequency electromagnetic fields (ELF-EMF) at 50 Hz and 1 milliTesla for up to 3 hours. They found the EMF exposure triggered cancer cell death (apoptosis) by increasing oxidative stress and activating specific cellular pathways. This suggests ELF-EMF might have potential therapeutic applications against bone cancer, though this was only tested in laboratory cell cultures, not living organisms.
Ross CL, Teli T, Harrison BS. · 2015
Researchers exposed cells containing human opioid receptors to 5 Hz electromagnetic fields and found they reduced cellular activity (cAMP levels) 23% more effectively than morphine. The effect was frequency-specific, as 13 Hz EMF produced no significant changes. This suggests certain EMF frequencies might influence pain pathways in ways similar to opioid drugs, potentially offering therapeutic benefits without drug side effects.
Lewicka M et al. · 2015
Polish researchers exposed human blood platelets to electromagnetic fields from car electronics, physiotherapy equipment, and LCD monitors for 30 minutes. They found that all three sources caused oxidative stress (cellular damage from harmful molecules called free radicals), with car electronics producing the strongest effects. This suggests that common electronic devices may damage our blood cells and potentially contribute to diseases linked to oxidative stress.
Masoudian N et al. · 2015
Researchers exposed brain nerve cells to electromagnetic fields from power lines and appliances. EMF exposure caused glutamate, a crucial brain chemical, to fluctuate by up to 40%. This matters because glutamate disruptions are linked to neurological diseases and brain cell damage.
Jin H, Yoon HE, Lee JS, Kim JK, Myung SH, Lee YS. · 2015
Researchers exposed human lung cells to 60 Hz magnetic fields (1-2 mT) alone and combined with radiation or hydrogen peroxide to test whether EMFs might make cells more vulnerable to genetic damage. The magnetic fields alone caused no genetic damage, and they didn't make the cells more susceptible to damage when combined with other stressors. This suggests that power frequency magnetic fields at these levels don't compromise cellular genetic stability.
Yang G, Ren Z, Mei YA. · 2015
Researchers exposed rat brain cells to power line frequency magnetic fields (50 Hz) and found they significantly boosted GABA receptor activity - the brain's main calming system. This change could potentially affect sleep, anxiety, and seizure control, showing how electromagnetic fields may influence brain function.
Mahdavi SM, Sahraei H, Rezaei-Tavirani M, Najafi Abedi A. · 2015
Iranian researchers exposed rats to 40 Hz electromagnetic fields (the same frequency used in many electrical systems) for 21 days and tracked changes in behavior and metabolism. They found significant disruptions including altered body weight patterns, reduced appetite, elevated blood glucose levels, and decreased movement and exploration behaviors. These findings suggest that even relatively low-frequency electromagnetic fields can disrupt normal biological functions in mammals.
Todorović D, Prolić Z, Petković B, Kalauzi A. · 2015
Researchers exposed longhorn beetles to 50 Hz magnetic fields (the same frequency as power lines) and measured how their brain neurons responded. They found that square wave magnetic fields caused measurable changes in neural activity after 10-15 minutes of exposure, while sine wave fields did not. This demonstrates that even insects show biological responses to power-frequency magnetic fields, and that the waveform shape matters for biological effects.
Percherancier Y et al. · 2015
Researchers exposed mouse cells to 50 Hz magnetic fields for 24 hours to study whether these fields affect gap junctions (tiny channels that allow cells to communicate with each other). They found no impact on cell communication at the magnetic field strengths tested (0.4 and 1 mT), contradicting some previous studies that suggested power frequency fields could disrupt this cellular function.
Chung YH et al. · 2015
Researchers exposed rats to 60 Hz magnetic fields (the same frequency as household electricity) for 2-5 days and measured brain chemicals called neurotransmitters. They found significant changes in key brain chemicals including dopamine, serotonin, and norepinephrine across multiple brain regions. These neurotransmitters control mood, movement, and cognitive function, suggesting that magnetic field exposure can alter brain chemistry.
Patruno A, Tabrez S, Pesce M, Shakil S, Kamal MA, Reale M · 2015
Italian researchers exposed leukemia cells to extremely low frequency electromagnetic fields (the type emitted by power lines and household appliances) for 24 hours at 50 Hz. They found significant changes in three key cellular enzymes that control oxidative stress and cellular metabolism. These enzyme disruptions could help explain how EMF exposure might contribute to health problems at the cellular level.
Duan W et al. · 2015
Researchers exposed mouse reproductive cells to electromagnetic fields from power lines and cell phones to compare DNA damage. Both types caused genetic damage through different mechanisms - power line fields broke DNA strands while cell phone radiation caused oxidative damage to DNA bases.
Cheng Y et al. · 2015
Researchers exposed brain stem cells (neural progenitor cells) from stroke-damaged brains to 50 Hz magnetic fields at 0.4 mT for 7 days. The magnetic field exposure significantly increased both cell multiplication and the development of these stem cells into neurons. This suggests that extremely low frequency electromagnetic fields might help brain recovery after stroke by promoting the growth of new brain cells.
