Colliding Dimensions

5G Dangers, 5th Generation Wireless Technology. Health and Environmental Impacts

This timely article published in December 2018 documents with foresight the health impacts of 5G Wireless Technology which is now being applied Worldwide.

This first EU 5G Appeal was initially submitted in September 2017 to the European Commission demanding a moratorium on the increase of cell antennas for planned 5G expansion. Concerns over health effects from higher radiation exposure include potential neurological impacts, infertility, and cancer.

It will provide faster speeds (up to 100 times) and higher capacity transmissions to carry the massive amount of data that will be generated from the Internet of Things (IoT), driverless cars, smart cities and towns, drones, and for faster video streaming. There are even plans to provide 5G from space, meaning thousands of satellites to cover every square inch of the earth with wireless radiation.

5G will include the higher millimeter wave frequencies never before used for internet and communications technology. The 5G deployment proposes to add frequencies in the microwave spectrum in the low- (0.6 GHz – 3.7 GHz), mid- (3.7GHz – 24 GHz), and high-band frequencies (24 GHz and higher) for faster communications. As these higher frequencies do not travel far and are blocked by buildings, this system will have to use a dense network of fixed antennae outdoors every 300 meters as well as indoor systems. This radiation, like the 2G, 3G, 4G telecommunications systems, has not had pre market testing for long term health effects despite the fact that people will be exposed continuously to this microwave radiation.

It is argued that the addition of this added high frequency 5G radiation to an already complex mix of lower frequencies, will contribute to a negative public health outcome both from both physical and mental health perspectives.

Environmental effects of existing RF radiation have also been ignored. 5G will massively increase the microwave and millimeter wave radiation in our environment, and will have a detrimental effect on wildlife and trees. 5G will substantially increase exposure to radio–frequency electromagnetic fields RF-EMF, that has already been proven to be harmful for humans, animals and the environment.

Millimeter wavelengths (at high intensity) have been used in military applications in active denial systems (non-lethal crowd control weapons). (See this)

Some research on non-thermal effects has shown that millimeter wavelengths target cell membranes and have adverse biological effects as well as clinical effects such as cataracts, immune system alterations and physiological effects on the heart and blood pressure. Betzalal et al (2018) have demonstrated that the sweat glands which are coiled structures in the upper layers of the skin can act as antenna receiver for 5G sub-THz band wavelengths. If not stopped, there may be a serious illness explosion.

Biological Effects of Dirty Electricity with Emphasis on Diabetes and Multiple Sclerosis

Dirty electricity is a ubiquitous pollutant. It ﬂows along wires and radiates fromthem and involves both extremely low frequency electromagnetic ﬁelds and radiofrequency radiation. Until recently, dirty electricity has been largely ignored bythe scientiﬁc community. Recent inventions of metering and ﬁlter equipment providescientists with the tools to measure and reduce dirty electricity on electrical wires.Several case studies and anecdotal reports are presented. Graham/Stetzer (GS)ﬁlters have been installed in schools with sick building syndrome and both staffand students reported improved health and more energy. The number of studentsneeding inhalers for asthma was reduced in one school and student behaviorassociated with ADD/ADHD improved in another school. Blood sugar levels forsome diabetics respond to the amount of dirty electricity in their environment.Type 1 diabetics require less insulin and Type 2 diabetics have lower blood sugarlevels in an electromagnetically clean environment. Individuals diagnosed withmultiple sclerosis have better balance and fewer tremors. Those requiring a canewalked unassisted within a few days to weeks after GS ﬁlters were installed intheir home. Several disorders, including asthma, ADD/ADHD, diabetes, multiplesclerosis, chronic fatigue, ﬁbromyalgia, are increasing at an alarming rate, as iselectromagnetic pollution in the form of dirty electricity, ground current, and radiofrequency radiation from wireless devices. The connection between electromagneticpollution and these disorders needs to be investigated and the percentage of peoplesensitive to this form of energy needs to be determined.

Most of the research on the biological effects of nonionizing radiation is done at oneof two frequency ranges: extremely low frequency (ELF) associated with electricity(50/60 Hz) and radio frequency (RF) associated with wireless telecommunication
devices (800 MHz to 2.5 GHz range). An intermediate frequency range, at the lowend of the RF spectrum (kHz), ﬂows along and radiates from wires (dirty electricity)and thus has characteristics of the two major types of electromagnetic pollutionmentioned above. Scientists doing research on the biological effects of power linefrequencies seldom measure this frequency range and thus ignore the effects it mighthave on health.Recent advances in ﬁltering technology (Graham/Stetzer or GS ﬁlters) andmeasuring equipment (microsurge meter) enable scientists to test for dirty electricityand to reduce it on indoor wires. In this article, case studies are presented ofindividuals who have beneﬁted after the dirty electricity in their environment wasreduced. This technology provides scientists with the tools to monitor, reduce, andexperiment with a frequency range that, until now, has been largely ignored andit may help those who suffer from symptoms of electromagnetic hypersensitivity(EHS).Dirty ElectricityPoor power quality, also known as dirty electricity, has been a concern for theelectric utility for decades. Dirty electricity refers to electromagnetic energy thatﬂows along a conductor and deviates from a pure 60-Hz sine wave (Figure 1). It hasboth harmonic and non harmonic (transient) components and emerged as a problemin the late 1970s with the increasing use of electronic devices that produce nonlinearloads. Karl Stahlkopf, a vice president of the Electric Power Research Institute(EPRI), estimates that dirty power costs U.S. industry between $4 and $6 billion ayear, and that it is likely to get worse before it can be mitigated. EPRI expects that70% of all electricity produced within the U.S. will ﬂow through electronic devicesby 2002, compared with 30% in 1999 (Fortune, 1999).Dirty electricity is ubiquitous. It is generated by electronic equipment suchas computers, plasma televisions, energy efﬁcient appliances, dimmer switches, as...

...well as arcing on electrical conductors caused by loose wires or contact with trees(Figure 2). Dirty electricity is thus produced within buildings but can also enterbuildings from neighbors who share the same transformer. Mobile or broadcastantennas, if not properly ﬁltered, can also contribute to high frequencies onelectrical wires in nearby buildings.The IEEE 519-1992 recommends installing ﬁlters to control harmonicdistortions on power lines. With 5 kV and higher voltage distribution lines theIEEE identiﬁes voltage notching, which produces both harmonic and nonharmonicfrequencies in the radio frequency (RF) range and, as such, can introduce harmfuleffects associated with spurious RF. Industry uses large capacitors to protectsensitive equipment from power surges, especially in production line work, wheremalfunctions and down time are costly. Until now ﬁlters have not been availablefor in home use.Professor Martin Graham from UC Berkeley and power quality expert, DaveStetzer, President of Stetzer Electric in Wisconsin, have designed a ﬁlter that canbe used inside buildings to clean the power that enters the building as well as thedirty electricity generated within the building. The Graham/Stetzer (GS) ﬁlter is acompact unit that plugs into an electrical outlet (Figure 3). It contains an electricalcapacitor that shorts-out the high frequency transients on the circuit and is mosteffective when placed close to the appliance generating the dirty electricity. The GSﬁlter has optimum ﬁltering capacity between 4 and 100 kHz (Graham, 2000, 2002).In Russia, the safety guidelines for electric and magnetic ﬁeld exposure arefrequency speciﬁc. For frequencies between 5 Hz and 2 kHz, the guideline is 25 V/mfor electric ﬁelds and 0.25 T (2.5 mG) for magnetic ﬁelds. For frequencies between 2and 400 kHz, the guidelines are lower by a factor of 10. Since energy is proportionalto frequency, the energy is 1,000 times higher at 60 kHz than it is at 60 Hz.

Equipment used to reduce and monitor dirty electricity inside buildings: the Graham/Stetzer filter and the microsurge meter.

The microsurge meter (Figure 3), also designed by Graham and Stetzer,measures the energy associated with dirty electricity in GS units with a range from1 to 1999 and an accuracy of ±5% (Graham, 2003). The Health Department ofthe Republic of Kazakhstan (2003) has stated that any reading on the microsurgemeter exceeding 50 is unacceptable and steps must be taken to lower such readings.Experience with this meter suggests that values below 30 GS units are undesirableand that extremely sensitive individuals may not see any beneﬁts until the values areat or below 20 GS units. In some extremely dirty environments it is not possible toachieve such low values.In the following, a number of case studies are presented.Case StudiesGS ﬁlters have been placed in homes, ofﬁces, and schools. People reporthaving better sleep, more energy, and less pain. They document cognitiveimprovements in memory and concentration. Symptoms of radio wave sickness orelectrical hypersensitivity (Table 1) are often reduced or eliminated in the ﬁlteredenvironment.GS ﬁlters placed in one Wisconsin school that had sick building syndrome,signiﬁcantly improved power quality. Shortly after the ﬁlters were installed, thehealth and energy level of staff and students began to improve. According to theDistrict Nurse, of the 37 students in the school who used inhalers on a daily basis,only 3 required inhalers and only for exercise-induced asthma after the ﬁlters werein place (Sbraggia, 2002).GS ﬁlters were placed in a Toronto school and approximately 50% of theteachers documented improvements in energy, performance, mood, and/or healthin a single blind study (Havas et al., 2004). Student behavior, especially at theelementary level, also improved. The symptoms that changed were ones we associate...

Neurological: Headaches, dizziness, nausea, difﬁculty concentrating, memory loss,irritability, depression, anxiety, insomnia, fatigue, weakness, tremors, musclespasms, numbness, tingling, altered reﬂexes, muscle and joint paint, leg/foot pain,“ﬂu-like” symptoms, fever. More severe reactions can include seizures, paralysis,psychosis, and stroke.

Cardiac: Palpitations, arrhythmias, pain or pressure in the chest, low or high bloodpressure, slow or fast heart rate, shortness of breath.

Ophthalmologic: Pain or burning in the eyes, pressure in/behind the eyes,deteriorating vision, ﬂoaters, cataracts.

Others: Digestive problems, abdominal pain, enlarged thyroid,testicular/ovarian pain, dryness of lips, tongue, mouth, eyes, great thirst,dehydration, nosebleeds, internal bleeding, altered sugar metabolism, immuneabnormalities, redistribution of metals within the body, hair loss, pain in the teeth,deteriorating ﬁllings, impaired sense of smell, ringing in the ears.

∗Note: These symptoms resemble symptoms associated with electrical hypersensitivity.

...with attention deﬁcit disorder (ADD) and attention deﬁcit hyperactivity disorder(ADHD). This begs the question, “How much of the increase in ADD/ADHDamong young people is due to electromagnetic pollution and poor electromagnetichygiene?”People with situational tinnitus (ringing in the ears that is present only in certainenvironments, often where RF is present) have documented improvements as wellafter the ﬁlters were installed in their home, as have those individuals who areotherwise healthy (Havas and Stetzer, 2004). Two diseases we seldom associatewith electromagnetic hypersensitivity are diabetes and multiple sclerosis (MS). Whatfollows are case studies that document the response to dirty electricity of diabeticsand those with MS.DiabetesTwo case studies are presented. (1) A 51-year old male with Type 2 diabetes whodoes not take medication and (2) an 80-year old female with Type 1 diabetes whotakes insulin twice a day. A 51-year old male with Type 2 diabetes monitoreddirty electricity in his environment and his blood sugar levels randomly throughoutthe day for approximately one month in 2003. The microsurge meter was not yetavailable to measure dirty electricity so he used a Protek 506 Digital Multimeter andmeasured the peak-to-peak voltage. His blood sugar levels were positively correlatedwith the amount of dirty electricity in his environment (Figure 4). One day he was...

Figure 4. Fifty-one year old male with Type 2 diabetes.His plasma glucose levels correlatewith the dirty electricity in his environment. Insert shows exposure on one day to a veryhigh level of dirty electricity and this is reﬂected in elevated blood sugar.

...exposed to very high levels of dirty electricity and this was reﬂected in exceptionallyhigh levels of blood sugar. He noticed that his blood sugar levels remained lowwhen he was in his truck away from power lines and antennas and when he wasin a wilderness setting. In an electromagnetically dirty environment his blood sugarlevels would increase within minutes.An 80-year old female with Type 1 diabetes, who monitors her blood sugartwice daily—once in the morning upon awakening (fasting plasma glucose) and oncein the evening before supper—had her home in Arizona ﬁltered by an electrician. Hewas able to reduce the dirty electricity in her home from an average of 800 GS unitsto 13 GS units. As soon as the dirty electricity in her home was reduced, her bloodsugar began to drop. Her average fasting plasma glucose levels without the ﬁlterswas 171mg/dL and this dropped to an average of 119 with the ﬁlters (Figure 5).During this period her insulin injections were reduced from a daily average of 36units to 9 units.Her evening plasma glucose did not change after the ﬁlters were installed inher home but they did change on days she spent away from home. Levels wereparticularly high after spending time in a casino. Casinos are likely to have highlevels of dirty electricity but stress may also have contributed to higher levels ofblood sugar (Hinkle and Wolf, 1950).Multiple SclerosisOne teacher in the Wisconsin school that was ﬁltered had been diagnosed withmultiple sclerosis (MS). She was extremely tired, had double vision, had cognitive...

Figure 5. Eighty-year old female with Type 1 diabetes, who takes insulin twice daily.Fasting plasma glucose levels and insulin injections with and without Graham/Stetzer ﬁltersare shown.

...difﬁculties and could not remember the names of the students in her 4th gradeclass. Her health would improve during the summer but her symptoms returnedin September. She assumed her problems were mold-related but her symptoms didnot improve after the mold was removed from the school. Once the school wasﬁltered her symptoms disappeared. Similar stories prompted studies with peoplewho had MS.Havas began to work with people diagnosed with MS, who had difﬁcultywconclalking and who used canes or walkers. The ﬁrst person she worked with noticedimprovements within 24 h. At that stage Havas assumed this was a powerful placeboeffect but the subject’s symptoms continued to improve weekly and regressed onlyduring wet weather, which had always been a problem for this subject. Several otherpeople with MS were able to walk unassisted after a few days to weeks with the GSﬁlters and Havas began to videotape those who gave her permission to do so.One of those individuals is a 27-year old male who had been diagnosed withprimary progressive MS two years earlier. He walked with a cane or did “wallwalking” at home (holding onto the wall or furniture for balance). He had tremors,was exceptionally tired, and was beginning to have difﬁculty swallowing. Three daysafter 16 GS ﬁlters were placed in his home his symptoms began to disappear. Thedirty electricity in his home was reduced from 135–410 GS units to 32–38 GS units.He assumed his body was recovering spontaneously but he had been diagnosedwith progressive MS and not relapsing/remitting MS, so spontaneous recovery wasunlikely in his case.A week after the ﬁlters were installed in his home he had enough energy to goshopping with his father. He did not take his cane because he had not needed it, but after a couple of hours in the store his symptoms reappeared and he had difﬁcultywalking to the car. His tremors began to subside three hours after arriving home.This experience has been repeated on several occasions and he now knows that ifhe goes into an environment with dirty electricity his MS symptoms reappear.Figure 6 is taken from a video before the ﬁlters were installed in his home andtwo weeks later. Prior to the ﬁlters his walk was stilted and slow. He staggeredand resembled the gait of someone who was intoxicated. Two weeks after the ﬁlterswere installed his walk was normal with no signs of MS. During this period hebegan to put on weight, was sleeping better, and had fewer tremors and more energy(Figure 7).Some other observations that are notable is that his mother had been sufferingfrom hot ﬂashes at night associated with menopause and these came to an end afterthe ﬁlters were installed and his father experienced several episodes of vertigo weeklyand these became less frequent.

These case studies and anecdotal reports suggest that dirty electricity is biologicallyactive. Once dirty electricity is reduced, people’s health improves. For some it isreﬂected in more normal blood sugar levels, for others symptoms of MS are reduced,and for still others tinnitus disappears and behavior resembling ADD/ADHDimproves. Since dirty electricity is becoming ubiquitous large fractions of thepopulation are being exposed to this pollutant and some are being adverselyaffected.

Diabetes, multiple sclerosis, ADD/ADHD, asthma chronic fatigue, andﬁbromyalgia are all increasing in the population and the reasons for this increaseare poorly understood. Dirty electricity may be one of the contributors to theseillnesses.

According to Philips and Philips (2006) 3% of the population haselectromagnetic hypersensitivity (EHS) and 35% have symptoms of EHS. If thesepercentages apply to diabetics then as many as 5–60 million diabetics worldwidemay be responding to the poor power quality in their environment (Wild et al.,2004). Evidence from laboratory studies documents that insulin release and insulin-binding capacity to receptors cells is reduced by electromagnetic ﬁelds (Li et al.,2005; Sakurai et al., 2004). It is further known that stress increases blood sugarlevels in diabetics and that exposure to electromagnetic energy induces stressproteins at various frequencies (Blank and Goodman, 2004; Hinkle and Wolf,1950).

Dirty electricity can now be monitored with meters and reduced with ﬁlters,providing scientists with the tools needed for research. What is presented here isa handful of studies, many preliminary, with dramatic results. This area warrantsfurther investigation to determine the mechanisms involved and the percentage ofthe population affected.

Exposure to 1800 MHz radiofrequency radiation induces oxidative damage to mitochondrial DNA in primary cultured neurons

Increasing evidence indicates that oxidative stress may be involved in the adverse effects of radiofrequency (RF) radiation on the brain. Because mitochondrial DNA (mtDNA) defects are closely associated with various nervous system diseases andmtDNA is particularly susceptible to oxidative stress, the purpose of this study was to determine whether radiofrequency radiation can cause oxidative damage to mtDNA. In this study, we exposed primary cultured cortical neurons to pulsed RF electromagnetic fields at a frequency of 1800 MHz modulated by 217 Hz at an average special absorption rate (SAR) of 2 W/kg. At 24 h after exposure, we found that RF radiation induced a significant increase in the levels of 8-hydroxyguanine (8-OHdG), a common biomarker of DNA oxidative damage, in the mitochondria of neurons. Concomitant with this finding, the copy number of mtDNA and the levels of mitochondrial RNA (mtRNA) transcripts showed an obvious reduction after RF exposure. Each of these mtDNA disturbances could be reversed by pretreatment with melatonin, which is known to be an efficient antioxidant in the brain. Together, these results suggested that 1800 MHz RF radiation could cause oxidative damage to mtDNA in primary cultured neurons. Oxidative damage to mtDNA may account for the neurotoxicity of RF radiation in the brain.

The world-wide and rapidly growing use of mobile phones (MP) has raised considerable concerns about their potentially hazardous effects on human health. Compared to the other organs, the brain is exposed to relatively high specific absorption rates (SAR) due to the close proximity of the mobile telephone device to the head. Exposure to radiofrequency (RF) radiation emitting from MP has been postulated to result in a variety of neurological effects, including headaches, changes in sleep patterns, modifications in neuronal electrical activity, increases in the permeability of the blood–brain barrier (BBB) and disturbances in neurotransmitter release (Hossmann and Hermann, 2003; Repacholi, 1998; Valentini et al., 2007). There is growing evidence to suggest that RF radiation induces oxidative stress in the brain and in other tissues (Ilhan et al., 2004; Irmak et al., 2002; Koylu et al., 2006; Moustafa et al., 2001; Oktem et al., 2005; Ozguner et al., 2005a,b; Sokolovic et al., 2008; Yurekli et al., 2006). Oxidative stress is known to be essential for pathophysiological processes in the brain, and it plays critical roles in cell apoptosis, general and specific gene expression, DNA damage, cell proliferation, inflammation process and mitochondrial dysfunction (Hayashi et al., 2008; Lin and Beal, 2006). The involvement of oxidative stress in manifold processes is compatible with the diverse nature of the observed effects induced by RF radiation (Balik et al., 2005; Cleary et al., 1996; Diem et al., 2005; Koylu et al., 2006; Schwarz et al., 2008; Zhao et al., 2007a,b). Thus, oxidative stress may be involved in the adverse effects of RF radiation on the nervous system.

Mitochondria are the major sites of production of reactive oxygen species (ROS). ROS are toxic by-products of respiration, and excess ROS are known to cause oxidation of unsaturated fatty acid, proteins, and DNA. Mitochondrial DNA (mtDNA) is particularly susceptible to oxidative stress for a variety of reasons, including its lack of protective histone-like proteins, its insubstantial capacity for repair following damage, and its proximity to the respiratory chain in the mitochondrial inner membrane (Evans et al., 2004). MtDNA damage is reflected by the presence of mtDNA mutation, by a decline in mtDNA copy number, and by a reduced number of mitochondrial RNA (mtRNA) transcripts (Ide et al., 2001). Each of these types of mtDNA damage can amplify oxidative stress by encoding the deficient critical proteins for the respiratory chain, which exacerbates further production of ROS and aggravates the oxidative damage to mitochondrial function (Evans et al., 2004; Wallace, 1999). Indeed, oxidative damage to mtDNA contributes to mitochondrial dysfunction in various mitochondrial-related diseases including aging, neurodegenerative diseases and ischemia. The presence of mtDNA mutations is closely related to a variety of neurological symptoms, such as migraine, dementia, and ataxia (Lin and Beal, 2006; Taylor and Turnbull, 2005; Xu et al., 2009). Therefore, there is the possibility that RF radiation could cause oxidative damage to mtDNA in nerve cells, and this may account for the adverse effects of RF radiation on the nervous system. In order to address this, we exposed primary cultured cortical neurons to 1800 MHz radiofrequency radiation at the SAR value of 2 W/kg. We observed a striking degree of oxidative damage to mtDNA in these neurons. In addition, we discovered that these oxidative injuries to mtDNA could be successfully prevented by melatonin, a pineal neurohormone with known antioxidant capacity especially in the brain (Lee et al., 2001; Sokolovic et al., 2008).

Are The Higher 5G Frequencies More Dangerous?

Kevin Mottus of the US Brain Tumor Association says that within the radio frequency portion of the electromagnetic spectrum, the higher the frequency, the more dangerous the radiation is. There are a couple of reasons why Kevin says that this is the case.

First, the higher the frequency the more energy the waves carry. Since the millimeter waves are basically from .5 to .1 inches in length, not the several feet of 4G, it is very dense wireless radiation hitting our bodies.

And second, the 5G waves pulse more, more waves per second hit our bodies, and therefore it beats up our cells more. Microwave radiation doesn’t cause cancer directly through the direct pulling on an electron like happens with ionizing radiation, but it causes cancer indirectly by increasing free radicles and by damaging DNA.

5G Millimeter Waves Disrupt Our Body’s Energy Fields

Every living creature emits an electric or energy field around it. Some people claim to be able to see it and we have machines that can detect it. These energy fields are one of the ways that the cells of our bodies communicate with each other. This communication is an important part of our body’s ability to stay healthy.

Microwave waves as used in cellular and WiFi devices disrupt our bodies energy fields interfering with our cells ability to communicate with each other and heal. Since the millimeter wave lengths from 5G (24 GHz up to 300 GHz) are so much smaller (see below chart) than the waves from previous cellular generations, they pulse more often per second and disrupt our body’s energy field more times per second.

As Dr. Barrie Trower (a British physicist & microwave expert) put it, our bodies have internal clocks of sorts that control various functions of the body. They do things such as regulate hormones as well as functions of particular organs.

If our body’s communication energy fields are disrupted it can mess up our heart beat or brain activity for example as well as how our hormones are regulated. This can cause a whole host of different problems within our bodies. These manifest as various diseases.

5G Frequencies Absorb Oxygen

The 60 GHz frequency, which was used for a short time in new WiFi routers, absorbs oxygen. Because of this there has been great concern by scientists that being around this frequency can make it hard for people to absorb oxygen themselves.

Other frequencies within the 5G range do this too, but the 60 GHz frequency is known for it.

Because 5G frequencies beat up on the cells with more hits per second, and because it carries more energy, it causes more oxidative damage to DNA strands than the lower frequencies. This literally breaks DNA single and double strands.

Besides the damage to the person receiving the DNA strand breaks, DNA damage can also be passed down to future generations. Eggs in a woman’s ovaries are particularly vulnerable to this DNA damage, affecting the woman’s future children.

Pretty much every health issue known to be caused by microwave radiation, such as cancer, DNA damage, brain tumors, breast tumors and infertility, are all increased with increase in frequency.

Why Do Many Main Stream Sources Say 5G Is Safe?

The short answer is they lie, plain and simple. There are no two ways about it. Let me explain by giving you a bit longer of an answer.

If you asked most people in America today if politicians are corrupt, they would quickly say yes (except their guy). The technology industry, especially telecom, is a very large lobby. And corrupt politicians have very creative ways of getting kickbacks from lobbyists.

I have noticed since I have been researching and studying this topic the last several years, that it is always government, technology or technology industry funded (even through advertising) sources that claim 5G and other EMF Radiation is safe. They completely ignore the hundreds of independently funded (no dog in the fight) scientific studies showing that this non-ionizing radiation causes things like cancer, brain tumors, breast tumors, DNA damage, crib death and infertility.

PC Magazine Example

A good example of this is an article published by PC Magazine entitled “Is 5G Safe?“. In this article the author Sascha Segan says:

He is the one ignoring actual facts. I could write a whole article just shredding his deceit and misrepresentation in this article. But for now I will just talk about this one quote.

There are two fundamental problems with his statements. First even those frequencies he is referencing have been proven by many independently (non biased) scientific studies to cause all of the things I listed above. And second the frequencies he lists that have been used for a long time are not 5G at all. This is where he gets really deceptive.

5G cellular networks use both 5G and 4G frequencies. When scientists talk about “5G Radiation” they are referring to the 5G millimeter wave frequencies which range from around 24 GHz to 300 GHz. Since these frequencies don’t travel as far and get obstructed easier, cellular companies also use frequencies from the lower ranges typically thought of as 1G, 2G, 3G & 4G systems.

So Sascha Segan is basically calling these lower frequencies (from 1G, 2G, 3G & 4G) “5G” because they are being used in 5G cellular networks, even though they are not the 5G millimeter frequencies. They are just added to “5G networks” to help the 5G frequencies. So he is lying in other words. Here is an article that explains how both the higher and lower frequencies are used in 5G cellular networks “What Is the 5G Spectrum? Definition“.

Forbes Magazine Example

Forbes is another example of misinformation out there on this topic. In their article “Is 5G Making You Sick? Here’s What Experts Say” the author Emily Laurence states:

Oh brother. It is amazing to me that they can write this kind of stuff with a straight face. Again there are literally hundreds of non-biased, independently funded, peer reviewed scientific studies that link this radiation to the diseases I listed above and a host of others. There are also hundreds of scientists and doctors from more than 35 countries writing letters to their respective governments warning of the harm that will come from the 5G roll out. I link to many of the studies on the scientific studies page of this website.

BMJ Medical Journal Example

I found their article entitled “Stop global roll out of 5G networks until safety is confirmed, urges expert“, which is actually very fair. They did real journalism in this article. Instead of saying the main stream normal “since 5G Radiation is non-ionizing, it can’t possibly be harmful”, like many claim, they quoted scientists stating their claims as to why it is harmful. It didn’t say on the article who the author was, but I am impressed with whomever it was.

Best Ways To Protect Yourself From 5G Radiation

When it come to protecting yourself from 5G frequencies as well as all EMF Radiation, I take a two pronged approach. First I try to block and reduce as much radiation as possible so that my exposure is minimal. And since these methods only reduce, and don’t eliminate the radiation, I also use products that change the harmful man made EMF Radiation into more natural less harmful forms.

Blocking And Shielding 5G Radiation

As is shown in the above image showing a Wifi Router Guard , a lot of companies now make faraday containers and metallic mesh shielding pads and cloth that can block most of the RF Radiation cellular and WiFi devices emit, if used properly. I think every person should both have their WiFi router in a Wifi Router Guard, and their smart meter covered by a Smart Meter Guard. Those are very important first places to start.

The next thing to focus on is protecting yourself from the 5G and other EMF Radiation emitted by your cellphone, laptop & iPad. They make shielding phone cases and shielding laptop & iPad pads that will block a significant amount of the radiation from these devices. SafeSleeve is my favorite brand for these items. They are designed so much better than most of their competition, and they use top notch shielding fabrics.

Also I would not hold your cellphone up to your head like cellphone protection case companies show in their marketing. While these shielding cases do block a bunch of the radiation, some still goes around the case and into your body. It is my personal opinion that they definitely block enough to be worth having; I have tested them with meters my self (see my YouTube video). But it is still important to keep distance between the phone and your body.

One thing that helps with that is talking on speaker phone with the phone sitting on a table when possible. When this is not practical then I use a regular corded headset with a Ferrite Bead or two attached to the bottom. If you decide you want to use an Air Tube Headset, you will still need a Ferrite Bead attached to the bottom. I personally don’t use my air tube headset because they are all heavy and clunky. I talk about how to use all of these items in my article “Best Cellphone Radiation Protection Items – My Top Picks!“.

Neutralizing 5G Radiation

I used to consider these types of products snake oil until I finally read the science on them. Now I am very excited about them and I use them on all my devices. If you would like to read the science for yourself I explain it and link to the studies in my article “Aulterra EMF 5G Neutralizer Review“.

The secret of the Neutralizer lies in the crystalline matrix mixed into the ink of the Neutralizer patch. It literally changes the harmful man made EMF Radiation into a more natural, less harmful form. The neutralizer’s developer, Kim Dandurand identified the crystalline properties while engaged in a major environmental cleanup operation in 1996, in which it was used to neutralize chemical and radioactive waste from landfill sites.

He then paid a reputable lab (Quantum Biology Research Laboratories) to do some studies to determine whether the paramagnetic substance could be used to neutralize the EMFs from electronic equipment like it did the radioactive waste.

Well in closing I just want to encourage everyone reading this article to go the the links I linked in this article and do your own research. Don’t take what I or any other source says as truth without double checking it for yourselves.

Thank you for reading this article, especially if you made it here all the way to the end.

This article was created by the "Environmental Health Trust" and is to bring awareness to the dangers of Wi-fi and 5g. For more on this topic check out the book The Invisible rainbow.

Published peer reviewed science already indicates that the current wireless technologies of 2G, 3G and 4G – in use today with our cell phones, computers and wearable tech – creates (create) radiofrequency exposures which poses (pose) a serious health risk to humans, animals and the environment. Scientists are cautioning that before rolling out 5G, research on human health effects urgently needs to be done first to ensure the public and environment are protected.

“Small cells” are microwave antennas (basically shorter cell towers) rapidly being installed in public areas on utility poles and street lights in front of homes, parks and schools. Just like cell towers, these wireless antennas generate and emit microwave radiofrequency (RF) radiation to transmit 2G, 3G and 4G network signals. Companies soon plan to add a new technology called 5G which will use current 4G technology plus even higher frequencies. The higher frequencies include millimeter-wave emissions that were not previously released into public areas.

Companies state that these 4G and 5G antennas will increase the wireless radiation levels in the area so much that they are working to loosen several governments’ radiation limits in order to roll it out. More than 240 scientists published an appeal to the United Nations to reduce public exposure and called for a moratorium on 5G citing “established” adverse biological effects of RF radiation.

5G will utilize not only the frequencies currently in use, but also higher millimeter wave and sub-millimeter wave frequencies. Small cells being installed in cities are usually 4G technology with a wide variety of frequencies. Thus, when we consider the health impacts of 5G and small cells we are looking at research on current technologies and frequencies in use in addition to research on sub-millimeter and millimeter waves. The 5G standard is new there are no studies that have looked at long term human exposure to 5G. However the current body of research finding effects from current wireless technology provides enough data for scientists to call for a moratorium.

5g dangers

Published Reviews on 5G

“5G Wireless Expansion: Public Health and Environmental Implications” published in Environmental Research is a research review that documents the range of reported adverse effects of RF and millimeter waves—effects range from cancer to bacteria growth changes to DNA damage. The study concludes that “a moratorium on the deployment of 5G is warranted” and “the addition of this added high frequency 5G radiation to an already complex mix of lower frequencies, will contribute to a negative public health outcome ... from both physical and mental health perspectives” (Russell, 2018).

“Adverse Health Effects of 5G Mobile Networking Technology Under Real Life Conditions” published in Toxicology Letters identifies the wide-spectrum of adverse health effects of non-ionizing non-visible radiation and concludes that 5G mobile networking technology will affect not only the skin and eyes, but will have adverse systemic effects as well. They state that 5G will increase the cell tower densities by an order of magnitude. The researchers conclude that in aggregate, for the high frequency (radiofrequency-RF) part of the spectrum, currently published reviews show that RF radiation below the FCC guidelines can result in: carcinogenicity (brain tumors/glioma, breast cancer, acoustic neuromas, leukemia, parotid gland tumors), genotoxicity (DNA damage, DNA repair inhibition, chromatin structure), mutagenicity, teratogenicity, neurodegenerative diseases (Alzheimer’s Disease, Amyotrophic Lateral Sclerosis), neurobehavioral problems, autism, reproductive problems, pregnancy outcomes, excessive reactive oxygen species/oxidative stress, inflammation, apoptosis, blood-brain barrier disruption, pineal gland/melatonin production, sleep disturbance, headache, irritability, fatigue, concentration difficulties, depression, dizziness, tinnitus, burning and flushed skin, digestive disturbance, tremor, cardiac irregularities, adverse impacts on the neural, circulatory, immune, endocrine, and skeletal systems” and “from this perspective, RF is a highly pervasive cause of disease” (Kostoff et al., 2020).

“Towards 5G communication systems: Are there health implications?” published in the International Journal of Hygiene and Environmental Health is a research review detailing research findings that millimeter waves can alter gene expression, promote cellular proliferation and synthesis of proteins linked with oxidative stress, inflammatory and metabolic processes.” The researchers conclude, “available findings seem sufficient to demonstrate the existence of biomedical effects, to invoke the precautionary principle” (Di Ciaula, 2018).

“Systematic Derivation of Safety Limits for Time-Varying 5G Radiofrequency Exposure Based on Analytical Models and Thermal Dose” published in Health Physics documents how significant tissue heating can be generated by 5G technology’s rapid short bursts of energy. “The results also show that the peak-to-average ratio of 1,000 tolerated by the International Council on Non- Ionizing Radiation Protection guidelines may lead to permanent tissue damage after even short exposures, highlighting the importance of revisiting existing exposure guidelines” (Neufeld and Kuster, 2018). A review of studies on 6 to 100 GHz (Simkó and Mattsson 2019) funded by Deutsche Telekom of Germany found that “the available studies do not provide adequate and sufficient information for a meaningful safety assessment, or for the question about non-thermal effects.” The review stated, “here is a need for research regarding local heat developments on small surfaces, e.g., skin or the eye, and on any environmental impact.” This study cited research that found “the presence of sweat glands [120,121] and also capillaries in the dermis can cause locally elevated SAR levels [122]. The latter study showed that SAR levels in vessels could be up to 30 times higher than in the surrounding skin, depending on the diameter of the vessels.”

Simkó and Mattsson 2019 analyzed the quality of the selected studies according to specific criteria. The studies were categorized by the presence of sham/ control, dosimetry, positive control, temperature control, and whether the study was blinded. Of the 45 in vivo studies, 78% (35) demonstrated biological responses after exposure to MMW. However when analyzed for quality criteria, “only three publications were identified that met all five criteria [26,51,53].” (EHT note: These three publications found an effect.) Similarly, 31 of the 53 in vitro studies found an effect. However only 13 studies had 3 of the 5 criteria satisfied and the authors conclude that “the number of examinations and the quality criteria are insufficient for a statistical analysis. It should be stressed that this quality analysis covers all publications dealing with the responses/effects of exposure to 6 to 100 GHz MMW, irrespective of the endpoints tested. To perform a correlation analysis, a larger number of comparable studies (e.g., identical endpoints in a frequency group) would be required.”

The study “Physiological effects of millimeter-waves on skin and skin cells: An overview of the to-date published studies” published in Reviews on Environmental Health by Dariusz Leszczynski reviewed 99 studies and concluded that the “scientific evidence concerning the possible effects of millimeter-waves on humans is insufficient to devise science-based exposure limits and to develop science-based human health policies. The sufficient research has not been done and, therefore, precautionary measures should be considered for the deployment of the 5G, before the sufficient number of quality research studies will be executed and health risk, or lack of it, scientifically established.” “In conclusion, there is an urgent need for research on the biological and health effects of mm-waves because, using the currently available evidence on skineffects, the claims that “we know skin and human health will not be affected” as well as the claims that “we know skin and human health will be affected” are premature assumptions that lack sufficient scientific basis.” (PDF of Accepted Manuscript)

skin and emf

5G and Human Skin

A 2020 study published in the journal Environmental Research and Public Health investigated the combined exposure of 3 G mobile systems at 1950 MHz RF and UV found a 24-h RF exposure significantly reduced the MMP-1 enzyme concentration, caused by prior UV exposure. Although they did not find changes in cytokines due to exposure to RF alone or enhancment of the effects of UV radiation, their findings indicate changes after exposure and point to the importance of investigating this and other effects on skin. The authors conclude that, “the investigation of the possible adverse effects on the skin due to the high frequency electromagnetic fields become more and more important before the deployment of 5G mobile systems. Using this new technology, the absorption of exposure to RF in the skin will be enhanced. The skin will be the most important target organ of the RF exposure to 5G. Therefore, our approach of combined (i.e., consecutive) exposure to UV and RF might be important in future research related to 5G and skin.”

“The Human Skin as a Sub-THz Receiver – Does 5G Pose a Danger to It or Not?”, published in Environmental Research, and “The Modeling of the Absorbance of Sub-THz Radiation by Human Skin”, published in IEEE Transactions on Terahertz Science and Technology, are two papers by physicists presenting research that found higher 5G frequencies are intensely absorbed into human sweat ducts (in skin), at a much higher absorption levels than other parts of our skin’s tissues (Betzalel et al., 2017, Betzalel et al., 2018). In an article published in Environmental Research, researchers conclude, “We are raising a warning flag against the unrestricted use of sub-THz technologies for communication, before the possible consequences for public health are explored” (Betzalel, et al., 2018).

“Exposure of Insects to Radio-Frequency Electromagnetic Fields from 2 to 120GHz” published in Scientific Reports is the first study to investigate how insects (including the Western honeybee) absorb the higher frequencies (2GHz to 120GHz) to be used in the 4G/5G rollout. The scientific simulations showed increases in absorbed power between 3% to 370% when the insects were exposed to the frequencies. Researchers concluded, “This could lead to changes in insect behaviour, physiology, and morphology over time....” (Thielens et al., 2018)

According to Belyaev 2019, “the health effects of chronic MMW exposures may be more significant than for any other frequency range.” The abstract states that, “ Various responses to non-thermal microwaves (MW) from mobile communication including adverse health effects related to electro hypersensitivity, cancer risks, neurological effects, and reproductive impacts have been reported while some studies reported no such effects. This presentation provides an overview of the complex dependence of the MW effects on various physical and biological variables, which account for, at least partially, an apparent inconsistence in the published data. Among other variables, dependencies on carrier frequency, polarization, modulation, intermittence, electromagnetic stray fields, genotype, physiological traits, and cell density during exposure were reported. Nowadays, biological and health effects of 5G communication, which will use microwaves of extremely high frequencies (millimeter waves MMW, wavelength 1- 10 mm), are of significant public concern. It follows from available studies that MMW, under specific conditions of exposure at very low intensities below the ICNIRP guidelines, can affect biological systems and human health. Both positive and negative effects were observed in dependence on exposure parameters. In particular, MMW inhibited repair of DNA damage induced by ionizing radiation at specific frequencies and polarizations. To what extend the 5G technology and the Internet of Things will affect the biota and human health is definitely not known. However, based on possible fundamental role of MMW in regulation of homeostasis and almost complete absence of MMW in atmosphere due to effective absorption, which suggests the lack of adaptation to this type of radiation, the health effects of chronic MMW exposures may be more significant than for any other frequency range.”

millimeter waves dangers

The Bioeffects of Millimeter Waves Documented Years Ago

“Biological Effect of Millimeter Waves”, a Russian review on millimeter waves declassified by the CIA in 2012, reported multiple research findings and concluded that, “Morphological, functional and biochemical studies conducted in humans and animals revealed that millimeter wave caused changes in the body manifested in structural alterations in the skin and internal organs, qualitative and quantitative changes of the blood and bone marrow composition and changes of the conditioned reflex activity, tissue respiration, activity of enzymes participating in the process of tissue respiration and nucleic metabolism” (Zalyubovskaya, 1977).

“Current State And Implications Of Research On Biological Effects Of Millimeter Waves: A Review Of The Literature” published in BioElectroMagnetics reviewed dozens of research findings on low-intensity millimeter waves and determined that the reported, “MMW effects could not be readily explained by temperature changes during irradiation.” The review concludes by questioning the adequacy of regulatory limits stating that, “Safety limits for these types of exposure are based solely on predictions of energy deposition and MMW heating, but in view of recent studies this approach is not necessarily adequate” (Pakhomov et al., 1998).

“Skin Heating and Injury by Prolonged Millimeter-Wave Exposure: Theory Based on a Skin Model Coupled to a Whole Body Model and Local Biochemical Release From Cells at Supraphysiologic Temperatures”, published in IEEE Transactions On Plasma Science concludes that a consequence of MMW heating is the alteration of cell-membrane permeability. Nearby skin layers are affected by the biophysical mechanism of biochemical release through cell membranes. “The released molecules are delivered to other skin regions by diffusion and into the bloodstream by perfusion, where according to our hypothesis, the molecules interact with susceptible cells. This raises the possibility of additional indirect injury at nearby deeper skin regions that experience insignificant heating. Biochemical release may also lead to injury at distant sites within the body by perfusion clearance that transfers molecules into the systemic circulation to reach other susceptible cells” (Stewart et al., 2006).

Siegel et al, 2010 published in Electronics Records reviewed a series of experiments “which show changes in cell membrane potential and the action potential firing rate of cortical neurons under short (1 min) exposures to continuous-wave 60 GHz radiation at mW/cm2 power levels, more than 1000 times below the US govern- ment maximum permissible exposure.” “At power levels of approximately 300 nW/cm2 and above, we observed strong inhibition of the action potential firing rate in some of the neurons, and increased firing in others, perhaps indicating the functional heterogeneity in the studied neuronal population. ...These results are believed to be the first positive correlative measurements of real-time changes in neuronal activity with ultra- low-power millimetre-wave exposures. The experiments point to changes in membrane channel opening....”

Yes, Adding More Cell Antennas Will Increase Exposures in Communities

A 2018 study published in Annals of Telecommunications found increased RF- EMF exposure from small cell LTE networks in two urban cities in France and the Netherlands. Researchers measured the RF-EMF from LTE (Long-Term Evolution) MC (macro cells meaning large cell towers) and SC networks (low- powered small cell base stations) and found that the small cell networks increased the radio emissions from base stations (called downlink) by a factor of 7–46 while decreasing the radio emissions from user equipment exposure (called ) by a factor of 5–17. So while the devices themselves could emit less radiation, the cell antennas will increase the levels from cell antennas (Mazloum et al., 2019). This study shows the increased exposures would be involuntary. We can turn our phones off, but we cannot turn off the antennas in the neighborhood.

An Australian study published in the Journal of Exposure Science & Environmental Epidemiology also found that children in kindergartens with nearby antenna installations had nearly three-and-a-half times higher RF exposures than children with installations further away by more than 300 meters (Bhatt et al., 2016).

A 2018 multi-country study published in Environment International measured RF in several countries. It found that cell phone tower radiation is the dominant contributor to RF exposure in most outdoor areas; exposure in urban areas was higher and that exposure has drastically increased. As an example, the measurements the researchers took in Los Angeles, USA were 70 times higher than the US EPA estimate 40 years ago (Sagar et al., 2018).

As an example of how rapidly RF is increasing from wireless antennas, a 2014 published study from Environmental Research looked at RF in three European cities and found in just one year (between April 2011 and March 2012) that the total RF-EMF exposure levels in all outdoor areas in combination increased by 57.1% in Basel, by 20.1% in Ghent and by 38.2% in Brussels. “Exposure increase was most consistently observed in outdoor areas due to emissions from mobile phone base stations” (Urbinello et al., 2014).

Another study, published in Environment International, looked at 529 children in Denmark, the Netherlands, Slovenia, Switzerland and Spain who wore meters around the waist or carried in a backpack during the day and placed close to the bed at night. Researchers found “the largest contributors to total personal environmental RF-EMF exposure were downlink (meaning from cell tower base stations) and broadcast” (Birks et al., 2018).

Cell tower radiation is a significant contribution to our daily exposure to RF. A study recently published in the International Journal of Environmental Research and Public Health equipped Australian adults with an RF measuring device in a small hip bag for approximately 24 consecutive hours. The study found “downlink and broadcast are the main contributors to total RF-EMF personal exposure.” Downlink (RF from mobile phone base station) contributed 40.4% of the total RF-EMF exposure (Zeleke et al., 2018).

Another published study in the Science of The Total Environment journal, gave 50 Korean parents and their child a measuring device for 48 hours found that “the contribution of base-station exposure to total RF-EMF exposure was the highest both in parents and children” (Choi et al., 2018).

kids on cell phone

Experts Warn that Measurement Techniques Do Not Adequately Measure 5G Exposures

A 2019 Report for the European Parliament Committee on Industry, Research and Energy published for the Policy Department for Economic, Scientific and Quality of Life Policies, entitled “5G Deployment: State of Play in Europe, USA, and Asia” explained that “5G radio emission fields are quite different to those of previous generations because of their complex beamformed transmissions in both directions – from base station to handset and for the return. Although fields are highly focused by beams, they vary rapidly with time and movement and so are unpredictable, as the signal levels and patterns interact as a closed loop system. This has yet to be mapped reliably for real situations, outside the laboratory.” “While the International Commission on Non-Ionizing Radiation

Protection (ICNIRP) issues guidelines for limiting exposure to electric, magnetic and electromagnetic fields (EMF), and EU member states are subject to Council Recommendation 1999/519/EC which follows ICNIRP guidelines, the problem is that currently it is not possible to accurately simulate or measure 5G emissions in the real world” (Blackman & Forge, 2019).

A 2020 European Parliament Briefing on the “Effects of 5G wireless communication on human health” reiterates the issues with measurements and also comments on how radiation limits are outdated stating in this summary, “The EU’s current provisions on exposure to wireless signals, the Council Recommendation on the limitation of exposure of the general public to electromagnetic fields (0 Hz to 300 GHz), is now 20 years old, and thus does not take the specific technical characteristics of 5G into account” (Karaboytcheva, 2020).

“Human Exposure to RF Fields in 5G Downlink” in IEEE International Communications Conference found “that 5G downlink RF fields generate significantly higher power density (PD) and specific absorption rate (SAR) than a current cellular system. This paper also shows that SAR should also be taken into account for determining human RF exposure in the mmW downlink” (Nasim & Kim, 2017).

The study “Human EMF Exposure in Wearable Networks for Internet of Battlefield Things” published in MILCOM 2019 – 2019 IEEE Military Communications Conference (MILCOM) is the first work that explicitly compares the human EMF exposure at different operating frequencies for on- body wearable communications. The study investigates the exposure effects of the human electromagnetic field (EMF) from on-body wearable devices and compares the results to illustrate how the technology evolution to higher frequencies can impact one’s health. It concludes that the results suggest the average specific absorption rate (SAR) at 60 GHz can exceed the regulatory guidelines within a certain separation distance between a wearable device and the human skin surface (Nasim & Kim, 2019).

Review Publications on Electromagnetic Radiation and RF

A 2019 literature review “Oxidative mechanisms of biological activity of low- intensity radiofrequency radiation” published in Electromagnetic Biology and Medicine found that 93 of the 100 peer-reviewed studies dealing with oxidative effects of low-intensity RFR, confirmed that RFR induces oxidative effects in biological systems (Yakymenko et al., 2016).

“Planetary Electromagnetic Pollution: It Is Time to Assess Its Impact” published in The Lancet Planetary Health documents the significant increase in environmental levels of radio-frequency (RF) electromagnetic wireless radiation over the past two decades. The study cites an evaluation that found 68.2% of 2,266 studies in humans, animals, and plants demonstrated

significant biological or health effects associated with exposure to electromagnetic fields. 89% of experimental studies that investigated oxidative stress endpoints showed significant effects and “radiofrequency electromagnetic radiation causes DNA damage apparently through oxidative stress.” The paper also highlights research that has associated RF exposure with altered neurodevelopment and behavioural disorders, structural and functional changes in the brain and the sensitivity of pollinators. “These findings deserve urgent attention.This weight of scientific evidence refutes the prominent claim that the deployment of wireless technologies poses no health risks at the currently permitted non-thermal radiofrequency exposure levels” (Bandara & Carpenter, 2018).

The review “Thermal and non-thermal health effects of low intensity non- ionizing radiation: An international perspective” published in Environmental Pollution by researchers of the European Cancer Environment Research Institute in Brussels, Belgium and the Institute for Health and the Environment, University at Albany, NY, USA reviews current research findings and states that, “the mechanism(s) responsible include induction of reactive oxygen species, gene expression alteration and DNA damage through both epigenetic and genetic processes.” The paper affirms that “exposure to low frequency and radiofrequency electromagnetic fields at low intensities poses a significant health hazard that has not been adequately addressed by national and international organizations such as the World Health Organization” (Belpomme et al., 2018).

The literature review “Effect of radiofrequency radiation on reproductive health” published by the Division of Reproductive Biology & Maternal Health, Child Health, Indian Council of Medical Research documents research that has found a link between radiofrequency radiation and oxidative stress and changes to the reproductive system including sperm count, motility, normal morphology and viability. The review concludes that the “available data indicate that exposure to EMF can cause adverse health effects. It is also reported that biological effects may occur at very low levels of exposure” (Singh et al., 2018).

Environmental Review published a 2010 landmark review study on 56 studies that reported biological effects found at very low intensities, including impacts on reproduction, permeability of the blood-brain barrier, behavior, cellular and metabolic changes, and increases in cancer risk (Lai & Levitt, 2010).

emf and the brain

Cancer and EMF

“Cancer epidemiology update, following the 2011 IARC evaluation of radiofrequency electromagnetic fields” published in Environmental Research is a comprehensive research review of RF effects in human and animal research. The review concludes that scientific evidence is now adequate to conclude radiofrequency radiation is carcinogenic to humans (Miller, 2018). Several previously published studies also concluded that RF causes various types of cancer, for example, Carlberg & Hardell, 2017 published in BioMed Research International; Atzman et al., 2016 published in the International Journal Cancer Clinical Research; and Peleg et al., 2018 published in Environmental Research.

The US National Toxicology Program (NTP) is a federal, interagency program that conducted a $30-million study designed to test the basis for federal safety limits.The study on, “Cell Phone Radio Frequency Radiation” found “clear evidence” of cancer, heart damage and DNA damage (NIEHS, 2018). The heart and brain cancers found in the NTP rats are the same cell type as tumors that researchers have found to be increasing in humans who have used cell phones for over 10 years as published in BioMed Research (Carlberg & Hardell, 2017). Thus, researchers assert in the International Journal of Oncology that the animal evidence from the NTP study confirms the human evidence associating radio frequency radiation exposure to cancer occurrences/developments (Carlberg & Hardell, 2019).

The 2018 report of final brain and heart tumor results from the The Ramazzini Institute (RI) Study on Base Station RF, published in Environmental Research was another large scale rat study that also found increases in the same heart cancers that the US National Toxicology Program (NTP) study found—yet the Ramazzini rats were exposed to much lower levels of RF than the NTP rats. In fact, all the RI radiation exposures were below FCC limits, as the study was specifically designed to test the safety of RF limits for cell tower/base stations (Falconi et al., 2018.) Thus, the Ramazzini study corroborates the NTP findings as published on the National Institutes of Health website.

“Tumor promotion by exposure to radiofrequency electromagnetic fields below exposure limits for humans” published in Biochemical and Biophysical Research Communications is a replication study that used very, very low RF exposures (lower than the Ramazzini and NTP study) and combined the RF with a known carcinogen. Researchers found elevated lymphoma and significantly higher numbers of tumors in the lungs and livers in animals exposed to both RF and the carcinogen, leading researchers to state that previous research published in the International Journal of Radiation Biology (Tillman et al., 2010) was confirmed and that “our results show that electromagnetic fields obviously enhance the growth of tumors” (Lerchl et al., 2015).

trees impacted by EMF

Environment and EMF

“A review of the ecological effects of radiofrequency electromagnetic fields (RF-EMF)” published in Environment International reviewed 113 studies finding RF-EMF had a significant effect on birds, insects, other vertebrates, other organisms and plants in 70% of the studies (Cucurachi et al., 2013). Development and reproduction in birds and insects were the most strongly affected. As an example of the several studies on wildlife impacts, a study published in the Bulletin of Environmental Contamination and Toxicology focused on RF emissions from antennas found increased sperm abnormalities in mice exposed to RF from GSM antennas (Otitoloju et al., 2009).

Published studies, in Toxicology International and Apidologie, on bees have found behavioral effects (Kumar et al., 2011; Favre 2011), while other studies from the International Journal of Environmental Sciences and the IIAS-InterSymp Conference attest to disrupted navigation (Goldsworthy, 2009; Sainudeen, 2011; Kimmel et al., 2007). Decreasing egg laying rate and reduced colony strength are documented in Science Direct and the Acta Systemica-IIAS International Journal (Sharma & Kumar, 2010; Harst et al., 2006).

Research has also found high levels of damage to trees from cell antenna radiation. For example, a field monitoring study, “Radiofrequency radiation injures trees around mobile phone base stations” published in the Science of The Total Environment –spanning 9 years, involving over 100 trees–found trees sustained more damage on the side of the tree facing the antenna (Waldmann- Selsam et al., 2016).

Expanded 4G, 5G and the Internet of Things (IoT) will increase overall use of all types of wireless frequencies.

A published review, in Environmental Research, of effects of Wi-Fi radiation entitled, “Wi-Fi is an important threat to human health” found that “repeated Wi-Fi studies show that Wi-Fi causes oxidative stress, sperm/testicular damage, neuropsychiatric effects including EEG changes, apoptosis, cellular DNA damage, endocrine changes, and calcium overload (Pall, 2018).

“The Impact of radiofrequency radiation on DNA damage and antioxidants in peripheral blood lymphocytes of humans residing in the vicinity of mobile phone base station” is a research study that compared people living close (within 80 meters) and far (more than 300 meters away) from cellular antennas found that the people living closer had several significant changes in their blood predictive of cancer development (Zothansanga et al., 2017). An earlier 2016 study, on genetic damage in humans populations exposed to radiation from mobile towers published in Archives of Environmental Contamination and Toxicology, evaluated 116 persons exposed to radiation from mobile towers and 106 control subjects, found DNA damage in peripheral blood lymphocytes (Gulati et al., 2016).

“Mortality by neoplasia and cellular telephone base stations”, published in Science of The Total Environment, is a 10 year study by the Belo Horizonte, Brazil Health Department and several universities in Brazil that found an elevated relative risk of cancer mortality at residential distances of 500 meters or less from cell installations (Dode et al., 2011). Shortly after this study was published, the city prosecutor sued several cell phone companies and requested that almost half of the city’s antennas be removed. Many antennas were dismantled.

The 2018 study, “Mobile Phone Base Station Tower Settings Adjacent to School Buildings: Impact on Students’ Cognitive Health” published in the American Journal of Men’s Health, investigated male students in schools near cell towers. The researchers concluded that exposure to higher RF levels is associated with negative impacts on motor skills, memory and attention (Meo et al., 2019). Examples of other effects linked to cell towers in research studies include neuropsychiatric problems, published in NeuroToxicology; elevated diabetes, published in the International Journal of Environmental Research and Public Health; headaches, published in Occupational and Environmental Medicine; sleep problems and genetic damage published in the French journal Pathologie Biologie.

A study published in 2018 International Conference on Power Energy, Environment and Intelligent Control (PEEIC) by IEEE entitled, “Effect of Mobile Tower Radiation on Microbial Diversity in Soil and Antibiotic Resistance” took soil samples from four different base stations located in Dausa city, India and control samples from soil far from stations and then isolated and evaluated the microorganisms in the soil. The researchers found greater antibiotic resistance in microbes present in soil near base stations compared to the control. The study concludes, “our findings suggest that mobile tower radiation can significantly alter the vital systems in microbes and turn them multidrug resistant (MDR) which is the most important current threat to public health” (Sharma et al., 2018).

Research on 3G and 4G

3G and 4G technology is still very much in use around the world. In addition, 5G devices will also have 4G emissions and 5G will utilize the frequencies currently used in 2G, 3G and 4G.

Published in General Physiology and Biophysics, a 2019 study titled, “Chromosome damage in human cells induced by UMTS mobile telephony radiation” examined human blood from healthy donors. The study found that 3G ) EMF/microwave radiation emissions from mobile telephones, within the current exposure limits, has significant genotoxic effects on human cells and advises that “human exposure to this EMF/radiation should be kept at levels as low as possible” (Panagopoulos, 2019). A series of landmark studies found that effects from microwaves on human lymphocytes can be dependant on carrier frequency (Markova et al., 2005), that Universal Mobile Telecommunications System (UMTS) 3G microwaves can affect chromatin and inhibit formation of DNA double-strand breaks (Belyaev et al., 2009), and that stem cells are most sensitive to microwave exposure (Markova et al., 2010) published in Environmental Health Perspectives, Bio Electro Magnetics, and Environmental Health Perspectives respectively. Children have more active stem cells.

The fourth generation (4G) of cellular technology called Long Term Evolution (LTE) was launched without premarket safety testing for long term exposure. Published research has found behavioral changes in mice (Broom et al., 2019), damage to the testes and reproductive potential in mice (Yu et al., 2019), reduction to EEG alpha power (Vecsei et al., 2018), modulation to resting state EEG on alpha and beta bands (Yang et al., 2017), and the ; alteration of spontaneous low frequency fluctuations induced by the acute LTE RF-EMF exposure (Lv et al., 2014); published in Bio Electro Magnetics, Science of the Total Environment, Scientific Reports, Clinical EEG and Neuroscience, and Clinical Neurophysiology respectively.

Published in Bio Electro Magnetics, a 2018 double‐blind, crossover, randomized, and counterbalanced design study about the modulation of brain functional connectivity by exposure to 4G LTE cell phone radiation found that acute LTE‐ EMF exposure did modulate connectivity in some brain regions.The authors conclude that, “Our results may indicate that approaches relying on network‐ level inferences can provide deeper insights into the acute effects of LTE‐EMF exposure with intensities below the current safety limits on human functional connectivity. In the future, we need to investigate the evolution of the effect over time” (Wei et al., 2018).

The Building Industry

Published in Building and Environment the article, “Building Science and Radiofrequency Radiation: What Makes Smart and Healthy Buildings” with a long list of authors, including former Microsoft Canada President Frank Clegg as well as Anthony Miller MD former Director of the Epidemiology Unit of the National Cancer Institute of Canada, review research studies finding adverse health effects below regulatory limits. The authors recommend reducing radiofrequency radiation in buildings by installing wired rather than wired internet connections and corded rather than cordless phones (Clegg et al., 2019).

The Collaborative for High Performance Schools (CHPS) has developed “Best Practices for LOW EMF Classrooms” that details how schools can replace wireless networks with wired networks. See CHPS Low EMF Criteria

cell towers and health

Cell Towers and Health

“Mobile Phone Infrastructure Regulation in Europe: Scientific Challenges and Human Rights Protection”, a 2014 publication in Environmental Science & Policy by human rights experts argue that cell tower placement is a human rights issue for children because “the protection of children is a high threshold norm in Human Right law and the binding language of the Convention on the Rights of the Child obliges States Parties to provide a higher standard of protection for children than adults” and “any widespread or systematic form of environmental pollution that poses a long-term threat to a child’s rights to life, development or health may constitute an international human rights violation.” The article concludes that the “dearth of legislation to regulate the installation of base stations (cell towers) in close proximity to children’s facilities and schools clearly constitutes a human rights concern...” (Roda & Perry, 2014).

“Safety Zone Determination for Wireless Cellular Tower – A Case Study from Tanzania” published in the International Journal of Research in Engineering and Technology evaluated the radiation levels and concluded that “respective authorities should ensure that people reside far from the tower by 120m or more depending on the power transmitted to avoid severe health effect” (Nyakyi et al., 2013).

“Long-term Exposure to Microwave Radiation Provokes Cancer Growth: Evidences from Radars and Mobile Communication Systems”, published in Experimental Oncology reviews research findings on RF-EMF and states that it is “becoming increasingly evident that [the] assessment of biological effects of non-ionizing radiation based on physical (thermal) approach used in recommendations of current regulatory bodies, including the International Commission on Non-Ionizing Radiation Protection (ICNIRP) Guidelines, requires urgent reevaluation.” The paper concluded that “everyday exposure of both occupational and general public to MW radiation should be regulated based on a precautionary principles which imply maximum restriction of excessive exposure” (Yakymenko et al., 2011).

Published in Electromagnetic Biology and Medicine, a cross-sectional case control study on genetic damage in individuals living near cell towers found genetic damage parameters of DNA were significantly elevated. “The genetic damage evident in the participants of this study needs to be addressed against future disease-risk, which in addition to neurodegenerative disorders, may lead to cancer” (Gandhi et al., 2015).

“Neurobehavioral Effects Among Inhabitants Around Mobile Phone Base Stations” published in NeuroToxicology, concludes that, “Inhabitants living nearby mobile phone base stations are at risk for developing neuropsychiatric problems and some changes in the performance of neurobehavioral functions either by facilitation or inhibition” and called for the revision of standard guidelines for public exposure to RER from mobile phone base station antennas” (Abdel-Rassoul et al., 2006).

“Epidemiological Evidence for a Health Risk from Mobile Phone Base Stations” published in the International Journal of Occupational Environmental Health reviewed ten epidemiological studies that assessed for health effects of mobile phone base stations and found that 8 of the 10 studies reported increased prevalence of adverse neurobehavioral symptoms or cancer in populations living at distances less than 500 meters from base stations. The review concludes that ”current guidelines may be inadequate in protecting the health of human populations” (Khurana et al., 2010).

“How Does Long Term Exposure To Base Stations And Mobile Phones Affect Human Hormone Profiles?” published in Clinical Biochemistry followed volunteers for six years and found that high radio frequency radiation had effects on pituitary–adrenal axis represented in the reduction of ACTH, cortisol, thyroid hormones, prolactin in young females, and testosterone levels (Eskander et al., 2012).

Published in the French journal, Pathologie Biologie a study of 530 people living near mobile phone masts reported more symptoms of headache, sleep disturbance, discomfort, irritability, depression, memory loss and concentration problems the closer they lived to the cellular antennas (Santini et al., 2002).

A study, “The Microwave Syndrome: A Preliminary Study in Spain” published in Electromagnetic Biology and Medicine found statistically significant associations between field intensity and the symptoms of fatigue, irritability, headaches, nausea, loss of appetite, sleeping disorder, depressive tendency, feeling of discomfort, difficulty in concentration, loss of memory, visual disorder, dizziness and cardiovascular problems (Navarro et al., 2003).

“Subjective Symptoms, Sleeping Problems, And Cognitive Performance In Subjects Living Near Mobile Phone Base Stations” published in Occupational and Environmental Medicine found a significant correlation between measured power density and headaches, fatigue, and difficulty in concentration in 365 subjects (Hutter et al., 2006). Published in NeuroToxicology, Abdel-Rassoul et al., 2007 found residents living beneath and opposite a long established mobile phone mast reported significantly higher occurrences of headaches, memory changes, dizziness, tremors, depressive symptoms and sleep disturbance than a control group.

“Increased Incidence of Cancer Near a Cell-Phone Transmitter Station” published in the International Journal of Cancer Prevention found a four-fold increase in the incidence of cancer among residents living within a 300 meter radius of a mobile phone mast after three and seven years of exposure (Wolf & Wolf, 2004).

“The Influence of Being Physically Near to a Cell Phone Transmission Mast on the Incidence of Cancer” published in Umwelt Medizin Gesellschaft, found a three-fold increase in the incidence of malignant tumours after five years of exposure in people living within a 400 meter radius of a mobile phone mast (Eger et al., 2004).

Panagopoulos, D., Johansson, O., & Carlo, G. (2015). Polarization: A Key Difference between Man-made and Natural Electromagnetic Fields, in regard to Biological Activity. Scientific Reports, 5(1). https://doi.org/10.1038/srep14914

Panagopoulos, D., Johansson, O., & Carlo, G. (2015). Real versus Simulated Mobile Phone Exposures in Experimental Studies. Biomed Research International, 2015, 1-8. https://doi.org/10.1155/2015/607053

Hardell, L., & Carlberg, M. (2019). Comments on the US National Toxicology Program technical reports on toxicology and carcinogenesis study in rats exposed to whole-body radiofrequency radiation at 900 MHz and in mice exposed to whole-body radiofrequency radiation at 1,900 MHz. International Journal Of Oncology, 54(1), 111-127. https://doi.org/10.3892/ijo.2018.4606

Carlberg, M., & Hardell, L. (2017). Evaluation of Mobile Phone and Cordless

Phone Use and Glioma Risk Using the Bradford Hill Viewpoints from 1965 on Association or Causation. Biomed Research International, 2017, 1-17. https://doi.org/10.1155/2017/9218486

Belyaev, I., Dean, A., Eger, H., Hubmann, G., Jandrisovits, R., & Kern, M. et al. (2016). EUROPAEM EMF Guideline 2016 for the prevention, diagnosis and treatment of EMF-related health problems and illnesses. Reviews On Environmental Health, 31(3). https://doi.org/10.1515/reveh-2016-0011

Belpomme, D., Hardell, L., Belyaev, I., Burgio, E., & Carpenter, D. (2018).

Thermal and non-thermal health effects of low intensity non-ionizing radiation: An international perspective. Environmental Pollution, 242(Part A), 643-658. https://doi.org/10.1016/j.envpol.2018.07.019

Research on People Near Cell Towers Links Exposure to Adverse Effects

Published in the Electromagnetic Biology and Medicine journal, “The Impact of radiofrequency radiation on DNA damage and antioxidants in peripheral blood lymphocytes of humans residing in the vicinity of mobile phone base station” is a research study that compared people living close (within 80 meters) and far (more than 300 meters away) from cellular antennas and found that the people living closer had several significant changes in their blood predictive of cancer development. The researchers controlled for various demographics, including the use of microwaves and wireless in the homes (Zothansiama et al., 2017).

“Mortality by neoplasia and cellular telephone base stations” is a 10 year study by the Belo Horizonte Brazil Health Department and several universities in Brazil that found an elevated relative risk of cancer mortality at residential distances of 500 meters or less from cell installations (Dode 2011). Shortly after this study was published, the city prosecutor sued several cell phone companies and requested that almost half of the city’s antennas be removed. Many antennas were dismantled.

A 2019 studyof students in schools near cell towers found their higher RF exposure was associated with impacts on motor skills, memory and attention (Meo 2019). Examples of other effects linked to cell towers in research studies include neuropsychiatric problems, elevated diabetes, headaches, sleep problemsand genetic damage. Such research continues to accumulate after the 2010 landmark review studyon 56 studies that reported biological effects found at very low intensities, including impacts on reproduction, permeability of the blood-brain barrier, behavior, cellular and metabolic changes, and increases in cancer risk (Lai and Levitt, 2010).

A published study entitled, “Effect of Mobile Tower Radiation on Microbial Diversity in Soil and Antibiotic Resistance” took soil samples from four different base stations located in Dausa city, and control samples from soil far from stations and then isolated and evaluated the microorganisms in the soil. The researchers found greater antibiotic resistance in microbes present in soil near base stations compared to the control and a statistical significant difference in pattern of antibiotic resistance was found with Nalidixic acid, and cefixime when used as antimicrobial agents. The study concludes, “our findings suggest that mobile tower radiation can significantly alter the vital systems in microbes and turn them multidrug resistant (MDR) which is most important current threat to public health.”

Cellular Antennas Create Measurable Increases in Radiation in the Area

A 2018 article published in The Lancet Planetary Health points to unprecedented increasing RF exposures (Bandara and Carpenter 2018). Another key finding from Zothansiama 2017was that homes closer to antennas had measurably higher radiation levels—adding to the documentation that antennas increase RF levels. An Australian study also found that children in kindergartens with nearby antenna installations had nearly three-and-a-half times higher RF exposures than children with installations further away (more than 300 meters (Bhatt 2016).

Research Finds that Cell Tower Base Station Radiation is the Dominant Contributor to Overall Environmental Radiation Exposures. A 2018 multi-country study that measured RF in several countries found that cell phone tower radiation is the dominant contributor to RF exposure in most outdoor areas exposure in urban areas was higher and that exposure has drastically increased. As an example, the measurements the researchers took in Los Angeles, USA were 70 times higher than the US EPA estimate 40 years ago (Sagar 2018).

As an example of how rapidly RF is increasing from wireless antennas, a 2014published study looked at RF in three European cities and found in just one year (between April 2011 and March 2012) that the total RF-EMF exposure levels in all outdoor areas in combination increased by 57.1% in Basel by 20.1% in Ghent and by 38.2% in Brussels (Urbinello 2014). “Exposure increase was most consistently observed in outdoor areas due to emissions from mobile phone base stations.”

Another study, Birks 2018, looked at 529 children in Denmark, the Netherlands, Slovenia, Switzerland and Spain who wore meters around the waist or carried in a backpack during the day and placed close to the bed at night. Researchers found “the largest contributors to total personal environmental RF-EMF exposure were downlink (meaning from cell tower base stations) and broadcast.”

A study on Australian adults where participants carried a measuring device in a small hip bag for approximately 24 consecutive hours also found “downlink and broadcast are the main contributors to total RF-EMF personal exposure.” Downlink (RF from mobile phone base station) contributed 40.4% of the total RF-EMF exposure (Zeleke 2018).

Another published study (Choi 2018) that gave 50 Korean adult child pairs a special radiation measuring device for 48 hours evaluated the types of radiation the participants were exposed to and found that “the contribution of base-station exposure to total RF-EMF exposure was the highest both in parents and children.” These two studies are an important example of the research that shows that radiation from base stations is the dominant contributor to a person’s cumulative exposure. Therefore we cannot only focus on a persons cell phone use as the way people are exposed to this radiation. People are exposed to wireless radiation even when they are not using a mobile device due to cell towers, antennas and hotspots and they have no control over this.

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Cell Antennas Increase Exposures in Communities

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Experts Warn that Measurement Techniques Do Not Adequately Measure 5G Exposures

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Review Publications on Electromagnetic Radiation and RF

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Belpomme, D., Hardell, L., Belyaev, I., Burgio, E., & Carpenter, D. (2018).

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Singh, R., Nath, R., Mathur, A. K., & Sharma, R. S. (2018). Effect of radiofrequency radiation on reproductive health. The Indian Journal of Medical

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Cancer

Miller, A., Morgan, L., Udasin, I., & Davis, D. (2018). Cancer epidemiology update, following the 2011 IARC evaluation of radiofrequency electromagnetic fields (Monograph 102). Environmental Research, 167, 673- 683. https://doi.org/10.1016/j.envres.2018.06.043

Carlberg, M., & Hardell, L. (2017). Evaluation of Mobile Phone and Cordless Phone Use and Glioma Risk Using the Bradford Hill Viewpoints from 1965 on Association or Causation. Biomed Research International, 2017, 1-17. https://doi.org/10.1155/2017/9218486

Atzmon, I., Linn, S., Richter, E., & Portnov, B. (2016).

Microwave/Radiofrequency (MW/RF) Radiation Exposure and Cancer Risk: Meta-Analysis of Accumulated Empirical Evidence. International Journal Of Cancer And Clinical Research, 3(1). https://doi.org/10.23937/2378- 3419/3/1/1040

Peleg, M., Nativ, O., & Richter, E. (2018). Radio frequency radiation-related cancer: assessing causation in the occupational/military setting. Environmental Research, 163, 123-133. https://doi.org/10.1016/j.envres.2018.01.003

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Falcioni, L., Bua, L., Tibaldi, E., Lauriola, M., De Angelis, L., & Gnudi, F. et al. (2018). Report of final results regarding brain and heart tumors in Sprague- Dawley rats exposed from prenatal life until natural death to mobile phone radiofrequency field representative of a 1.8GHz GSM base station environmental emission. Environmental Research, 165, 496-503. https://doi.org/10.1016/j.envres.2018.01.037

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Environment

Cucurachi, S., Tamis, W., Vijver, M., Peijnenburg, W., Bolte, J., & de Snoo, G. (2013). A review of the ecological effects of radiofrequency electromagnetic fields (RF-EMF). Environment International, 51, 116-140. https://doi.org/10.1016/j.envint.2012.10.009

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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. Bulletin Of Environmental Contamination

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Kumar, N., Sangwan, S., & Badotra, P. (2011). Exposure to cell phone radiations produces biochemical changes in worker honey bees. Toxicology International, 18(1), 70. https://doi.org/10.4103/0971-6580.75869

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Waldmann-Selsam, C., Balmori-de la Puente, A., Breunig, H., & Balmori, A. (2016). Radiofrequency radiation injures trees around mobile phone base stations. Science Of The Total Environment, 572, 554-569. https://doi.org/10.1016/j.scitotenv.2016.08.045

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https://doi.org/10.1177/1557988318816914

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Research on 3G and 4G

Panagopoulos, D. (2019). Chromosome damage in human cells induced by UMTS mobile telephony radiation. General Physiology And Biophysics, 38(05), 445-454. https://doi.org/10.4149/gpb_2019032

Markovà, E., Hillert, L., Malmgren, L., Persson, B., & Belyaev, I. (2005).

Microwaves from GSM Mobile Telephones Affect 53BP1 and γ-H2AX Foci in Human Lymphocytes from Hypersensitive and Healthy Persons. Environmental Health Perspectives, 113(9), 1172-1177. https://doi.org/10.1289/ehp.7561

Belyaev, I., Markovà, E., Hillert, L., Malmgren, L., & Persson, B. (2009).

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Markovà, E., Malmgren, L., & Belyaev, I. (2010). Microwaves from Mobile Phones Inhibit 53BP1 Focus Formation in Human Stem Cells More Strongly Than in Differentiated Cells: Possible Mechanistic Link to Cancer Risk. Environmental Health Perspectives, 118(3), 394-399. https://doi.org/10.1289/ehp.0900781

Broom, K., Findlay, R., Addison, D., Goiceanu, C., & Sienkiewicz, Z. (2019).

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Yu, G., Tang, Z., Chen, H., Chen, Z., Wang, L., & Cao, H. et al. (2020). Long-term exposure to 4G smartphone radiofrequency electromagnetic radiation diminished male reproductive potential by directly disrupting Spock3–MMP2- BTB axis in the testes of adult rats. Science Of The Total Environment, 698, 133860. https://doi.org/10.1016/j.scitotenv.2019.133860

Vecsei, Z., Knakker, B., Juhász, P., Thuróczy, G., Trunk, A., & Hernádi, I. (2018).

Short-term radiofrequency exposure from new generation mobile phones reduces EEG alpha power with no effects on cognitive performance. Scientific Reports, 8(1). https://doi.org/10.1038/s41598-018-36353-9

Yang, L., Chen, Q., Lv, B., & Wu, T. (2016). Long-Term Evolution Electromagnetic Fields Exposure Modulates the Resting State EEG on Alpha and Beta Bands. Clinical EEG And Neuroscience, 48(3), 168-175. https://doi.org/10.1177/1550059416644887

Lv, B., Chen, Z., Wu, T., Shao, Q., Yan, D., & Ma, L. et al. (2014). The alteration of spontaneous low frequency oscillations caused by acute electromagnetic fields exposure. Clinical Neurophysiology, 125(2), 277-286. https://doi.org/10.1016/j.clinph.2013.07.018

Wei, Y., Yang, J., Chen, Z., Wu, T., & Lv, B. (2018). Modulation of resting-state brain functional connectivity by exposure to acute fourth-generation long- term evolution electromagnetic field: An fMRI study. Bioelectromagnetics, 40(1), 42-51. https://doi.org/10.1002/bem.22165

Clegg, F., Sears, M., Friesen, M., Scarato, T., Metzinger, R., & Russell, C. et al. (2020). Building science and radiofrequency radiation: What makes smart and healthy buildings. Building And Environment, 176, 106324. https://doi.org/10.1016/j.buildenv.2019.106324

Compilation of Research Studies on Cell Tower Radiation and Health

Shahbazi-Gahrouei, D. (2017). Base transceiver station antennae exposure and human health. International Journal Of Preventive Medicine, 8(1), 77. https://doi.org/10.4103/ijpvm.ijpvm_180_17

Pearce, J. (2020). Limiting liability with positioning to minimize negative health effects of cellular phone towers. Environmental Research, 181, 108845. https://doi.org/10.1016/j.envres.2019.108845

Roda, C., & Perry, S. (2014). Mobile phone infrastructure regulation in Europe: Scientific challenges and human rights protection. Environmental Science & Policy, 37, 204-214. https://doi.org/10.1016/j.envsci.2013.09.009

Nyakyi, C., Mrutu, S., Sam, A., & Anatory, J. (2013). Safety zone determination for wireless cellular tower- a case study from Tanzania. International Journal Of Research In Engineering And Technology, 02(09), 194-201. https://doi.org/10.15623/ijret.2013.0209029

Yakymenko, I., Sidorik, E., Kyrylenko, S., & Chekhun, V. (2011). Long-term exposure to microwave radiation provokes cancer growth: evidences from radars and mobile communication systems. Experimental Oncology, 33, 62- 70. Retrieved 12 May 2020, from https://www.ncbi.nlm.nih.gov/pubmed/21716201.

Khurana, V., Hardell, L., Everaert, J., Bortkiewicz, A., Carlberg, M., & Ahonen, M. (2010). Epidemiological Evidence for a Health Risk from Mobile Phone Base Stations. International Journal Of Occupational And Environmental Health, 16(3), 263-267. https://doi.org/10.1179/oeh.2010.16.3.263

Eskander, E., Estefan, S., & Abd-Rabou, A. (2012). How does long term exposure to base stations and mobile phones affect human hormone profiles?. Clinical Biochemistry, 45(1-2), 157-161. https://doi.org/10.1016/j.clinbiochem.2011.11.006...

Navarro, E., Segura, J., Portolés, M., & Gómez‐Perretta de Mateo, C. (2003). The Microwave Syndrome: A Preliminary Study in Spain. Electromagnetic

Biology And Medicine, 22(2-3), 161-169. https://doi.org/10.1081/jbc- 120024625

Wolf, R., & Wolf, D. (2004). Increased incidence of cancer near a cell-phone transmitter station. International Journal Of Cancer Prevention, 1(2). Retrieved 13 May 2020, from https://citeseerx.ist.psu.edu/viewdoc/download? doi=10.1.1.652.9315&rep=rep1&type=pdf.

Eger, H., Hagen, K., Lucas, B., Vogel, P., & Voit, H. (2004). Increased incidence of cancer near a cell-phone transmitter station. Umwelt Medizin Gesellschaft, 17. Retrieved 12 May 2020, from http://avaate.org/IMG/pdf/20041118_naila.pdf.

The Bioeffects of Millimeter Waves Documented Years Ago

Declassified and Approved for release 2012/05/10: CIA- RDP88B01125R000300120005-6. (1977). Biological effect of millimeter radiowaves (pp. 116-119). Kiev: Vrachebnoye Delo.

Pakhomov, A., Akyel, Y., Pakhomova, O., Stuck, B., & Murphy, M. (1998).

Current state and implications of research on biological effects of millimeter waves: A review of the literature. Bioelectromagnetics, 19(7), 393-413. https://doi.org/10.1002/(sici)1521-186x(1998)19:7...>3.0.co;2- x

EMFscientist.org – International EMF Scientist Appeal. Emfscientist.org. (2020). Retrieved 12 May 2020, from https://www.emfscientist.org/index.php/emf- scientist-appeal.

Wang, Q., Zhao, X., Li, S., Wang, M., Sun, S., & Hong, W. (2017). Attenuation by a Human Body and Trees as well as Material Penetration Loss in 26 and 39GHz Millimeter Wave Bands. International Journal Of Antennas And Propagation, 2017, 1-8. https://doi.org/10.1155/2017/2961090

Stewart, D., Gowrishankar, T., & Weaver, J. (2006). Skin Heating and Injury by Prolonged Millimeter-Wave Exposure: Theory Based on a Skin Model Coupled to a Whole Body Model and Local Biochemical Release From Cells at Supraphysiologic Temperatures. IEEE Transactions On Plasma Science, 34(4), 1480-1493. https://doi.org/10.1109/tps.2006.878996

Papaioannou, A., & Samaras, T. (2011). Numerical Model of Heat Transfer in the Rabbit Eye Exposed to 60-GHz Millimeter Wave Radiation. IEEE Transactions On Biomedical Engineering, 58(9), 2582-2588. https://doi.org/10.1109/tbme.2011.2159502

Reviews

BioInitiative Report: A Rationale for Biologically-based Public Exposure Standards for Electromagnetic Fields (ELF and RF). The BioInitiative Report. (2020). Retrieved 12 May 2020, from https://bioinitiative.org/.

Moskowitz,, J. (2018). Annotated Bibliography of Scientific Papers Finding Evidence of Harm from Cell Phone Radiation Exposure [PDF]. Retrieved 12 May 2020, from https://drive.google.com/file/d/1zeM5L7- x4Xnu9B6SxpHPQ0J_dHIHMQCy/view.

PowerWatch. (2018). PowerWatch: 1,670 Peer-Reviewed Scientific Papers on Electromagnetic Fields and Biology or Health [PDF]. Retrieved 12 May 2020, from https://drive.google.com/file/d/19CbWmdGTnnW1iZ9p... ew.

Panagopoulos, D., Johansson, O., & Carlo, G. (2015). Real versus Simulated

Mobile Phone Exposures in Experimental Studies. Biomed Research International, 2015, 1-8. https://doi.org/10.1155/2015/607053

Le Pogam, P., Le Page, Y., Habauzit, D., Doué, M., Zhadobov, M., & Sauleau, R. et al. (2019). Untargeted metabolomics unveil alterations of biomembranes permeability in human HaCaT keratinocytes upon 60GHz millimeter-wave exposure. Scientific Reports, 9(1). https://doi.org/10.1038/s41598-019-45662- 6

Soubere Mahamoud, Y., Aite, M., Martin, C., Zhadobov, M., Sauleau, R., Le Dréan, Y., & Habauzit, D. (2016). Additive Effects of Millimeter Waves and 2- Deoxyglucose Co-Exposure on the Human Keratinocyte Transcriptome. PLOS ONE, 11(8), e0160810. https://doi.org/10.1371/journal.pone.0160810

Mandl, P., Pezzei, P., & Leitgeb, E. (2018). Selected Health and Law Issues Regarding Mobile Communications with Respect to 5G. 2018 International Conference On Broadband Communications For Next Generation Networks And Multimedia Applications (CoBCom), 1-5. https://doi.org/10.1109/cobcom.2018.8443980

Tripathi, S., Ben Ishai, P., & Kawase, K. (2018). Frequency of the resonance of the human sweat duct in a normal mode of operation. Biomedical Optics Express, 9(3), 1301. https://doi.org/10.1364/boe.9.001301

Wu, T., Rappaport, T., & Collins, C. (2015). The human body and millimeter- wave wireless communication systems: Interactions and implications. 2015 IEEE International Conference On Communications (ICC), 2423-2429. https://doi.org/10.1109/icc.2015.7248688

Wu, T., Rappaport, T., & Collins, C. (2015). Safe for Generations to Come: Considerations of Safety for Millimeter Waves in Wireless Communications.

IEEE Microwave Magazine, 16(2), 65-84. https://doi.org/10.1109/mmm.2014.2377587

Ramundo-Orlando, A. (2010). Effects of Millimeter Waves Radiation on Cell Membrane – A Brief Review. Journal Of Infrared, Millimeter, And Terahertz Waves, 31(12), 1400-1411. https://doi.org/10.1007/s10762-010-9731-z

Scientific Citations from the published study “Potential Risks to Human Health Originating from Future Sub-MM Communication Systems” by Paul Ben-Ishai, PhD and Yuri Feldman, PhD

Feldman, Y., & Ben-Ishai, P. (2017). Potential Risks to Human Health Originating from Future Sub-MM Communication Systems. Jerusalem. Retrieved from https://ehtrust.org/wp-content/uploads/Yuri-Feldm... Abstract.pdf

Feldman, Y., Puzenko, A., Ben Ishai, P., Caduff, A., & Agranat, A. (2008). Human Skin as Arrays of Helical Antennas in the Millimeter and Submillimeter Wave Range. Physical Review Letters, 100(12), 128102. https://doi.org/10.1103/physrevlett.100.128102

Hayut, I., Ben Ishai, P., Agranat, A., & Feldman, Y. (2014). Circular polarization induced by the three-dimensional chiral structure of human sweat ducts. Physical Review E, 89(4), 042715. https://doi.org/10.1103/physreve.89.042715

Hayut, I., Puzenko, A., Ben Ishai, P., Polsman, A., Agranat, A., & Feldman, Y. (2013). The Helical Structure of Sweat Ducts: Their Influence on the Electromagnetic Reflection Spectrum of the Skin. IEEE Transactions On Terahertz Science And Technology, 3(2), 207-215. https://doi.org/10.1109/tthz.2012.2227476

RESEARCH ON MILLIMETER WAVES

Gandhi, O., & Riazi, A. (1986). Absorption of Millimeter Waves by Human

Beings and its Biological Implications. IEEE Transactions On Microwave Theory And Techniques, 34(2), 228-235. https://doi.org/10.1109/tmtt.1986.1133316

Sypniewska, R., Millenbaugh, N., Kiel, J., Blystone, R., Ringham, H., Mason, P., & Witzmann, F. (2010). Protein changes in macrophages induced by plasma from rats exposed to 35GHz millimeter waves. Bioelectromagnetics, 31(8), 656-663. https://doi.org/10.1002/bem.20598

Ramundo-Orlando, A., Longo, G., Cappelli, M., Girasole, M., Tarricone, L., Beneduci, A., & Massa, R. (2009). The response of giant phospholipid vesicles to millimeter waves radiation. Biochimica Et Biophysica Acta (BBA) – Biomembranes, 1788(7), 1497-1507. https://doi.org/10.1016/j.bbamem.2009.04.006

Chen, Q., Lu, D., Jiang, H., & Xu, Z. (2008). [Effects of millimeter wave on gene expression in human keratinocytes]. Zhejiang Da Xue Xue Bao Yi Xue Ban, 37(1), 8-23. Retrieved 13 May 2020, from https://www.ncbi.nlm.nih.gov/pubmed/18275115.

Gapeev, A., Rubanik, A., Pashovkin, T., & Chemeris, N. (2007). [Thermoelastic excitation of acoustic waves in biological models under the effect of the high peak-power pulsed electromagnetic radiation of extremely high frequency]. Biofizika, 52(6), 92-1087. Retrieved 13 May 2020, from https://www.ncbi.nlm.nih.gov/pubmed/18225661.

Millenbaugh, N., Kiel, J., Ryan, K., Blystone, R., Kalns, J., & Brott, B. et al. (2006).

Comparison of blood pressure and thermal responses in rats exposed to millimeter wave energy or environmental heat. Shock, 25(6), 625-632. https://doi.org/10.1097/01.shk.0000209550.11087.f...

Usichenko, T., Edinger, H., Gizhko, V., Lehmann, C., Wendt, M., & Feyerherd, F.

(2006). Low-Intensity Electromagnetic Millimeter Waves for Pain Therapy. Evidence-Based Complementary And Alternative Medicine, 3(2), 201-207. https://doi.org/10.1093/ecam/nel012

Gugkova, O., Gudkov, S., Gapeev, A., Bruskov, V., Rubannik, A., & Chemeris, N. (2005). [The study of the mechanisms of formation of reactive oxygen species in aqueous solutions on exposure to high peak-power pulsed electromagnetic radiation of extremely high frequencies]. Biofizika, 50(5). Retrieved 13 May 2020, from https://www.ncbi.nlm.nih.gov/pubmed/16248149.

Isakhanian, V., & Trchunian, A. (2005). [Indirect and repeated electromagnetic irradiation of extremely high freguency of bacteria Escherichia coli]. Biofizika, 50(4). Retrieved 13 May 2020, from https://www.ncbi.nlm.nih.gov/pubmed/16212062.

Makar, V., Logani, M., Bhanushali, A., Kataoka, M., & Ziskin, M. (2004). Effect of millimeter waves on natural killer cell activation. Bioelectromagnetics, 26(1), 10-19. https://doi.org/10.1002/bem.20046

Lushnikov, K., Shumilina, Y., Yakushina, V., Gapeev, A., Sadovnikov, V., & Chemeris, N. (2004). Effects of Low-Intensity Ultrahigh Frequency Electromagnetic Radiation on Inflammatory Processes. Bulletin Of Experimental Biology And Medicine, 137(4), 364-366. https://doi.org/10.1023/b:bebm.0000035131.54215.c...

Sinotova, O., Novoselova, E., Glushkova, O., & Fesenko, E. (2004). [A comparison of the effects of millimeter and centimeter waves on tumor necrosis factor production in mouse cells]. Biofizika, 49(3). Retrieved 13 May 2020, from https://www.ncbi.nlm.nih.gov/pubmed/15327216.

Gapeev, A., Lushnikov, K., Shumilina, I., Sirota, N., Sadovnikov, V., & Chemeris N, N. (2003). [Effects of low-intensity extremely high frequency electromagnetic radiation on chromatin structure of lymphoid cells in vivo and in vitro]. Radiatsionnaya Biologiya Radioekologiya, 43(1), 87-92. Retrieved 13 May 2020, from https://www.ncbi.nlm.nih.gov/pubmed/12677665.

Lushnikov, K., Gapeedv, A., Shumilina, I., Shibaev, N., Sadovnikov, V., & Chmeris, N. (2003). [Decrease in the intensity of the cellular immune response and nonspecific inflammation upon exposure to extremely high frequency electromagnetic radiation]. Biofizika, 48(5). Retrieved 14 May 2020, from https://www.ncbi.nlm.nih.gov/pubmed/14582420.

Lushnikov, K., Gapeev, A., & Chemeris, N. (2002). [Effects of extremely high- frequency electromagnetic radiation on the immune system and systemic regulation of homeostasis]. Radiatsionnaya Biologiya Radioekologiya, 42(5). Retrieved 13 May 2020, from https://www.ncbi.nlm.nih.gov/pubmed/12449822.

Novoselova, E., Ogaĭ, V., Sinotova, O., Glushkova, O., Sorokina, O., & Fesenko, E. (2002). [Effect of millimeter waves on the immune system in mice with experimental tumors]. Biofizika, 47(5). Retrieved 13 May 2020, from https://www.ncbi.nlm.nih.gov/pubmed/12397969.

Ushakov, V., Alipov, E., Shcheglov, V., & Belyaev, I. (2000). Nonthermal effects of extremely high-frequency microwaves on chromatin conformation in cells in vivo-dependence on physical, physiological, and genetic factors. IEEE Transactions On Microwave Theory And Techniques, 48(11), 2172-2179. https://doi.org/10.1109/22.884211

Szabo, I., Rojavin, M., Rogers, T., & Ziskin, M. (2001). Reactions of keratinocytes to in vitro millimeter wave exposure. Bioelectromagnetics, 22(5), 358-364. https://doi.org/10.1002/bem.62

D’Andrea, J., & Chalfin, S. (2000). Effects of Microwave and Millimeter Wave Radiation on the Eye. Radio Frequency Radiation Dosimetry And Its Relationship To The Biological Effects Of Electromagnetic Fields, 395-402. https://doi.org/10.1007/978-94-011-4191-8_43

Mason, P., Walters, T., Nelson, M., & Nelson, D. (2000). Skin heating effects of millimeter-wave irradiation-thermal modeling results. IEEE Transactions On Microwave Theory And Techniques, 48(11), 2111-2120. https://doi.org/10.1109/22.884202

Walters, T., Blick, D., Johnson, L., Adair, E., & Foster, K. (2000). Heating and pain sensation produced in human skin by millimeter waves. Health Physics, 78(3), 259-267. https://doi.org/10.1097/00004032-200003000-00003

Haas, A., Le Page, Y., Zhadobov, M., Sauleau, R., Dréan, Y., & Saligaut, C. (2017).

Effect of acute millimeter wave exposure on dopamine metabolism of NGF- treated PC12 cells. Journal Of Radiation Research, 58(4), 439-445. https://doi.org/10.1093/jrr/rrx004

Haas, A., Le Page, Y., Zhadobov, M., Sauleau, R., & Le Dréan, Y. (2016). Effects of 60-GHz millimeter waves on neurite outgrowth in PC12 cells using high- content screening. Neuroscience Letters, 618, 58-65. https://doi.org/10.1016/j.neulet.2016.02.038

Le Dréan, Y., Mahamoud, Y., Le Page, Y., Habauzit, D., Le Quément, C., Zhadobov, M., & Sauleau, R. (2013). State of knowledge on biological effects at 40–60 GHz. Comptes Rendus Physique, 14(5), 402-411. https://doi.org/10.1016/j.crhy.2013.02.005

Sivachenko, I., Medvedev, D., Molodtsova, I., Panteleev, S., Sokolov, A., & Lyubashina, O. (2016). Effects of Millimeter-Wave Electromagnetic Radiation on the Experimental Model of Migraine. Bulletin Of Experimental Biology And Medicine, 160(4), 425-428. https://doi.org/10.1007/s10517-016-3187-7

Soghomonyan, D., Trchounian, K., & Trchounian, A. (2016). Millimeter waves or extremely high frequency electromagnetic fields in the environment: what are their effects on bacteria?. Applied Microbiology And Biotechnology, 100(11), 4761-4771. https://doi.org/10.1007/s00253-016-7538-0

References on Millimeter waves in Military Non Lethal Weapon Program

Non-Lethal Weapons Program > About > Frequently Asked Questions > Active Denial System FAQs. Jnlwp.defense.gov. Retrieved 13 May 2020, from

https://jnlwp.defense.gov/About/Frequently-Asked-Q... System-FAQs/.

The Human Effects Advisory Panel. (2008). A Narrative Summary and Independent Assessment of the Active Denial System. Penn State Applied Research Laboratory. Retrieved from https://jnlwp.defense.gov/Portals/50/Documents/Fu... Lethal_Weapons/HEAP.pdf

LeVine, S. (2009). The Active Denial System A Revolutionary, Non-lethal Weapon for Today’s Battlefield. Washington, DC: National Defense University Center for Technology and National Security Policy.

Law, D. (2012). Active Denial Technology (ADT). Presentation.
Devyatkov N. Effect of electromagnetic radiation of a millimeter wavelength range on biological objects. Sov. Phys. Uspekhi. 1974;16:568. doi: 10.1070/PU1974v016n04ABEH005308. – DOI
Devyatkov N.D., Golant M.B., Betsky O.V. Millimeter Waves and Their Role in Vital Processes. Radio and Svyaz; Moscow, Russia: 1991.

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