Scientific Studies Showing Adverse Biological Effects + Damage From Wi-Fi

A nice list of studies about WLAN:

https://stopsmartmeters.org.uk/papers-finding-adverse-biological-effects-damage-to-health-from-wi-fi/

Wi-Fi papers

  1. Atasoy H.I. et al., 2013. Immunohistopathologic demonstration of deleterious effects on growing rat testes of radiofrequency waves emitted from conventional Wi-Fi devices. Journal of Pediatric Urology 9(2): 223-229. Immunohistopathologic demonstration of deleterious effects on growing rat testes of radiofrequency waves emitted from conventional Wi-Fi devices - PubMed

  2. Avendaño C. et al., 2012. Use of laptop computers connected to internet through Wi-Fi decreases human sperm motility and increases sperm DNA fragmentation. Fertility and Sterility 97(1): 39-45. Use of laptop computers connected to internet through Wi-Fi decreases human sperm motility and increases sperm DNA fragmentation - PubMed

  3. Avendaño C. et al., 2010. Laptop expositions affect motility and induce DNA fragmentation in human spermatozoa in vitro by a non-thermal effect: a preliminary report. American Society for Reproductive Medicine 66th Annual Meeting: O-249 http://wifiinschools.org.uk/resources/laptops+and+sperm.pdf)

  4. Aynali G. et al., 2013. Modulation of wireless (2.45 GHz)-induced oxidative toxicity in laryngotracheal mucosa of rat by melatonin. Eur Arch Otorhinolaryngol 270(5): 1695-1700. Modulation of wireless (2.45 GHz)-induced oxidative toxicity in laryngotracheal mucosa of rat by melatonin - PubMed

  5. Gumral N. et al., 2009. Effects of selenium and L-carnitine on oxidative stress in blood of rat induced by 2.45-GHz radiation from wireless devices. Biol Trace Elem Res. 132(1-3): 153-163. Effects of selenium and L-carnitine on oxidative stress in blood of rat induced by 2.45-GHz radiation from wireless devices - PubMed

  6. Havas M. et al., 2010. Provocation study using heart rate variability shows microwave radiation from 2.4GHz cordless phone affects autonomic nervous system. European Journal of Oncology Library Vol. 5: 273-300. :: International Commission for Electromagnetic Safety :: part 2.

  7. Havas M. and Marrongelle J. 2013. Replication of heart rate variability provocation study with 2.45GHz cordless phone confirms original findings. Electromagn Biol Med 32(2): 253-266. Replication of heart rate variability provocation study with 2.4-GHz cordless phone confirms original findings - PubMed

  8. Maganioti A. E. et al., 2010. Wi-Fi electromagnetic fields exert gender related alterations on EEG. 6th International Workshop on Biological Effects of Electromagnetic fields. http://www.istanbul.edu.tr/6internatwshopbioeffemf/cd/pdf/poster/WI-FI%20ELECTROMAGNETIC%20FIELDS%20EXERT%20GENDER.pdf

  9. Margaritis L.H. et al., 2013. Drosophila oogenesis as a bio-marker responding to EMF sources. Electromagn Biol Med., Epub ahead of print. Drosophila oogenesis as a bio-marker responding to EMF sources - PubMed

  10. Naziroğlu M. and Gumral 2009. Modulator effects of L-carnitine and selenium on wireless devices (2.45 GHz)-induced oxidative stress and electroencephalography records in brain of rat. Int J Radiat Biol. 85(8): 680-689. Modulator effects of L-carnitine and selenium on wireless devices (2.45 GHz)-induced oxidative stress and electroencephalography records in brain of rat - PubMed

  11. Nazıroğlu M. et al., 2012. 2.45-Gz wireless devices induce oxidative stress and proliferation through cytosolic Ca2+ influx in human leukemia cancer cells. International Journal of Radiation Biology 88(6): 449–456. http://www.ncbi.nlm.nih.gov/pubmed/22489926

  12. Nazıroğlu M. et al., 2012b. Melatonin modulates wireless (2.45 GHz)-induced oxidative injury through TRPM2 and voltage gated Ca(2+) channels in brain and dorsal root ganglion in rat. Physiol Behav. 105(3): 683-92. Melatonin modulates wireless (2.45 GHz)-induced oxidative injury through TRPM2 and voltage gated Ca(2+) channels in brain and dorsal root ganglion in rat - PubMed

  13. Oksay T. et al., 2012. Protective effects of melatonin against oxidative injury in rat testis induced by wireless (2.45 GHz) devices. Andrologia doi: 10.1111/and.12044, Epub ahead of print. Protective effects of melatonin against oxidative injury in rat testis induced by wireless (2.45 GHz) devices - PubMed

  14. Papageorgiou C. C. et al., 2011. Effects of Wi-Fi signals on the p300 component of event-related potentials during an auditory hayling task. Journal of Integrative Neuroscience 10(2): 189-202. Effects of wi-fi signals on the p300 component of event-related potentials during an auditory hayling task - PubMed

(Wi-Fi alters brain activity in young adults: http://wifiinschools.org.uk/resources/wifi+brain+July+2011.pdf)

  1. Shahin S. et al., 2013. 2.45 GHz Microwave Irradiation-Induced Oxidative Stress Affects Implantation or Pregnancy in Mice, Mus musculus. Appl Biochem Biotechnol 169: 1727–1751. 2.45 GHz microwave irradiation-induced oxidative stress affects implantation or pregnancy in mice, Mus musculus - PubMed

  2. Türker Y. et al., 2011. Selenium and L-carnitine reduce oxidative stress in the heart of rat induced by 2.45-GHz radiation from wireless devices. Biol Trace Elem Res. 143(3): 1640-1650. Selenium and L-carnitine reduce oxidative stress in the heart of rat induced by 2.45-GHz radiation from wireless devices - PubMed

And here are a few more studies of similar microwave frequencies at low exposures (6V/m or below) (this is not comprehensive):

  1. Balmori A. 2010. Mobile phone mast effects on common frog (Rana temporaria) tadpoles: the city turned into a laboratory. Electromagn. Biol. Med. 29(1-2):31-35. Mobile phone mast effects on common frog (Rana temporaria) tadpoles: the city turned into a laboratory - PubMed

  2. Erdinc O. O. et al., 2003. Electromagnetic waves of 900MHz in acute pentylenetetrazole model in ontogenesis in mice. Neurol. Sci. 24:111-116 Electromagnetic waves of 900 MHz in acute pentylenetetrazole model in ontogenesis in mice - PubMed

  3. Fesenko E. E. et al., 1999. Stimulation of murine natural killer cells by weak electromagnetic waves in the centimeter range. Biofizika 44:737–741 [Stimulation of murine natural killer cells by weak electromagnetic waves in the centimeter range] - PubMed

  4. Fesenko E. E. et al., 1999. Microwaves and cellular immunity. I. Effect of whole body microwave irradiation on tumor necrosis factor production in mouse cells, Bioelectrochem. Bioenerg. 49:29–35 Microwaves and cellular immunity. I. Effect of whole body microwave irradiation on tumor necrosis factor production in mouse cells - PubMed

  5. Havas M. et al., 2010. Provocation study using heart rate variability shows microwave radiation from 2.4GHz cordless phone affects autonomic nervous system. European Journal of Oncology Library Vol. 5: 273-300 :: International Commission for Electromagnetic Safety :: part 2.

  6. Kesari K. K. and Behari J., 2009. Microwave exposure affecting reproductive system in male rats. Appl. Biochem. Biotechnol. 162(2):416-428 Microwave exposure affecting reproductive system in male rats - PubMed

  7. Kesari K. K. and Behari J., 2009. Fifty-gigahertz microwave exposure effect of radiations on rat brain. Appl. Biochem. Biotechnol. 158:126-139 Fifty-gigahertz microwave exposure effect of radiations on rat brain - PubMed

  8. Khurana V. G. et al., 2010. Epidemiological Evidence for a Health Risk from Mobile Phone Base Stations. Int. J. Occup. Environ. Health 16:263–267 Epidemiological evidence for a health risk from mobile phone base stations - PubMed

  9. Maier R. et al., 2004. Effects of pulsed electromagnetic fields on cognitive processes – a pilot study on pulsed field interference with cognitive regeneration. Acta Neurologica Scandinavica 110: 46-52 Effects of pulsed electromagnetic fields on cognitive processes - a pilot study on pulsed field interference with cognitive regeneration - PubMed

  10. Nittby H. et al., 2008. Cognitive impairment in rats after long-term exposure to GSM-900 mobile phone radiation. Bioelectromagnetics 29: 219-232 Cognitive impairment in rats after long-term exposure to GSM-900 mobile phone radiation - PubMed

  11. Novoselova E. G. et al., 1998. Stimulation of production of tumor necrosis factor by murine macrophages when exposed in vivo and in vitro to weak electromagnetic waves in the centimeter range Bofizika 43:1132–1333.

  12. Novoselova E. G. et al., 1999. Microwaves and cellular immunity. II. Immunostimulating effects of microwaves and naturally occurring antioxidant nutrients. Bioelectrochem. Bioenerg. 49:37–41 Microwaves and cellular immunity. II. Immunostimulating effects of microwaves and naturally occurring antioxidant nutrients - PubMed

  13. Otitoloju A. A. et al., 2010. Preliminary study on the induction of sperm head abnormalities in mice, Mus musculus, exposed to radiofrequency radiations from Global System for Mobile Communication Base Stations. Bull. Environ. Contam. Toxicol. 84(1):51-4. Preliminary study on the induction of sperm head abnormalities in mice, Mus musculus, exposed to radiofrequency radiations from global system for mobile communication base stations - PubMed

  14. Panagopoulos D. J.et al., 2010. Bioeffects of mobile telephony radiation in relation to its intensity or distance from the antenna. Int. J. Radiat. Biol. Vol 86(5):345-357. Bioeffects of mobile telephony radiation in relation to its intensity or distance from the antenna - PubMed

  15. Persson B. R. R. et al., 1997. Blood-brain barrier permeability in rats exposed to electromagnetic fields used in wireless communication. Wireless Networks 3: 455-461. http://www.hese-project.org/hese-uk/en/papers/persson_bbb_wn97.pdf

  16. Pyrpasopoulou A. et al., 2004. Bone morphogenic protein expression in newborn kidneys after prenatal exposure to radiofrequency radiation. Bioelectromagnetics 25:216-27 Bone morphogenetic protein expression in newborn rat kidneys after prenatal exposure to radiofrequency radiation - PubMed

  17. Salford L. G. et al., 2010. Effects of microwave radiation upon the mammalian blood-brain barrier. European Journal of Oncology Library Vol. 5:333-355 :: International Commission for Electromagnetic Safety :: part 2.

  18. Salford L. G., et al., 2003. Nerve cell damage in mammalian brain after exposure to microwaves from GSM mobile phones. Environ. Health Perspect. 111:881-883. Nerve cell damage in mammalian brain after exposure to microwaves from GSM mobile phones - PubMed

Hah hah :stuck_out_tongue_winking_eye:… this brings back memories of me getting cancelled and blocked from facebook early 2020 for posting a university of melbourne study on 3g radiation created many years ago… I was labeled for posting false information. Nice to see these studies make a comeback.

Here is the video that was flagged false by fakebook. Coincidentally the rollout of 5g towers was considered an “essential service” and coincided with the first lockdowns. In retrospect it was required to implement qr codes everywhere to track everyone. COVert IDentification.

“The truth about mobile phone and wireless radiation” – Dr Devra Davis

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Using a mobilephone or DECT-phone close to the head for a longer time i can feel the influence directly.
It is feeling like a direct disturbance of thinking with enhancing of confusion.
Now I am using none of it any more.

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Experiment with sleep, while phone or electrical devices are in the room, or out. Do it for several weeks, I believe there is a considerable difference. Makes me wonder if it affects channeling in any way?

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You are always surrounded and pervaded with radio waves.
Mainly with mobile phone radiation and WLAN from neigbours.
Only the intensity differs.

You can only feel free when you are under the earth with a minimum of 30 meters overburden.
Then you need about 30 minutes to recover - afterwards you can think like an arrow and there is no feeled “pressure” in your head any more. This effect has been confirmed by others.

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Would be lovely to sleep next to this tower!