Impacts of radio-frequency electromagnetic field (RF-EMF)

Impacts of radio-frequency electromagnetic
field (RF-EMF) from cell phone towers
and wireless devices on biosystem
and ecosystem – a review

 


Biology and Medicine
Review Article
BMID: BM-8 202


Review Article Biology and Medicine, 4 (4): 202–216, 2012
www.biolmedonline.com


Impacts of radio-frequency electromagnetic field (RF-EMF) from
cell phone towers and wireless devices on biosystem
and ecosystem – a review


S Sivani*, D Sudarsanam
Department of Advanced Zoology and Biotechnology, Loyola College, Chennai, Tamil Nadu, India.

Accepted: 3rd Dec 2012, Published: 6th Jan 2013

 


Abstract
This paper summarizes the effect of radio-frequency electromagnetic field (RF-EMF) from cell towers and wireless
devices on the biosphere. Based on current available literature, it is justified to conclude that RF-EMF radiation exposure can change neurotransmitter functions, blood-brain barrier, morphology, electrophysiology, cellular metabolism,
calcium efflux, and gene and protein expression in certain types of cells even at lower intensities. The biological
consequences of such changes remain unclear. Short-term studies on the impacts of RF-EMF on frogs, honey bees,
house sparrows, bats, and even humans are scarce and long-term studies are non-existent in India. Identification of
the frequency, intensity, and duration of non-ionizing electromagnetic fields causing damage to the biosystem and
ecosystem would evolve strategies for mitigation and would enable the proper use of wireless technologies to enjoy
its immense benefits, while ensuring one’s health and that of the environment.
Keywords: Radio-frequency electromagnetic field; cell phone tower; power density; SAR; non-ionizing radiation;
non-thermal.
Introduction
There has been an unprecedented growth in the
global communication industry in recent years
which has resulted in a dramatic increase in the
number of wireless devices. Mobile services
were launched in India in 1995 and it is one of the
fastest growing mobile telephony industries in
the world. According to the Telecom Regulatory
Authority of India (TRAI, 2012), the composition
of telephone subscribers using wireless form
of communication in urban area is 63.27% and
rural area is 33.20%. By 2013, it is estimated that
more than one billion people will be having cell
phone connection in India. This has led to the
mushrooming of supporting infrastructure in the
form of cell towers which provide the link to and
from the mobile phone. With no regulation on the
placement of cell towers, they are being placed
haphazardly closer to schools, creches, public
playgrounds, on commercial buildings, hospitals, college campuses, and terraces of densely
populated urban residential areas. Hence, the
public is being exposed to continuous, low
intensity radiations from these towers. Since the
electromagnetic radiations, also known as electrosmog cannot be seen, smelt or felt, one would
not realize their potential harm over long periods
of exposure until they manifest in the form of
biological disorders. Various studies have shown
the ill-effects of radio-frequency electromagnetic
field (RF-EMF) on bees, fruit flies, frogs, birds,
bats, and humans, but the long-term studies of
such exposures are inconclusive and scarce, and
almost non-existent in India (MOEF, 2010; DoT,
2010). In 2011, International Agency for Research
on Cancer (IARC), part of WHO, designated
RF-EMF from cell phones as a “possible human
carcinogen” Class 2B (WHO, 2011). Cancer, diabetes, asthma, infectious diseases, infertility,
neurodegenerative disorders, and even suicides
are on the rise in India. This invisible health hazard
pollution (IHHP) is a relatively new environmental
threat.
Electromagnetic radiation, in the form
of waves of electric and magnetic energy, have
been circulating together through space. The
electromagnetic spectrum includes radio waves,
microwaves, infrared rays, light rays, ultraviolet
rays, X-rays, and gamma rays (ARPANSA, 2011;
Review Article Biology and Medicine, 4 (4): 202–216, 2012
BMID: BM-8 203
FCC, 1999). The electromagnetic radiations are
of two types, one being ionizing radiations such
as X-rays and gamma rays, and the other being
non-ionizing radiations such as electric and
magnetic fields, radio waves, radio- frequency
band which includes microwaves, infrared,
ultraviolet, and visible radiation (Figure 1).
The biological effects of RF-EMF at molecular
level induce thermal and non-thermal damage,
which may be due to dielectric heating leading
to protein denaturation, polar molecular agitation, cellular response through molecular cascades and heat shock proteins, and changes
in enzyme kinetics in cells (Instituto Edumed,
2010). The three major physical parameters of
RF-EMF radiations is frequency, intensity, and
exposure duration. Although the non-ionizing
radiations are considered less dangerous than
ionizing radiation, over-exposure can cause
health hazards (FCC, 1999).
Electromagnetic Spectrum and RF-EMF Radiation
The RF-EMF radiations fall in the range of
10 MHz–300 GHz. Cell phone technology uses
frequencies mainly between 800 MHz and 3 GHz
and cell tower antenna uses a frequency of 900
or 1800 MHz, pulsed at low frequencies, generally known as microwaves (300 MHz–300 GHz).
Power Density and Specific Absorption Rate
(SAR)
Variables used in the measurement of these
radiations are power density, measured in watts
per meter squared (W/m2
) and specific absorption rate (SAR). The term used to describe the
absorption of RF-EMF radiation in the body is
SAR, which is the rate of energy that is actually absorbed by a unit of tissue, expressed in
watts per kilogram (W/kg) of tissue. The SAR
measurements are averaged either over the
whole body or over a small volume of tissue,
typically between 1 and 10 g of tissue. SAR
was set with the help of a phantom, known as
specific anthropomorphic mannequin (SAM)
derived from the size and dimensions of the
90th percentile large adult male reported in a
1988 US Army study who is 6 feet 2 inches
and weighed 200 pounds (Davis, 2010). SAR
is set at 1.6 W/kg averaged over 1 g of body
tissue in the US and Canada and 2 W/kg
averaged over 10 g of body tissue in countries
adopting the ICNIRP guidelines. The SAR is
used to quantify energy absorption to fields typically between 100 kHz and 10 GHz and encompasses radio-frequency radiation from devices
such as cellular phones up through diagnostic
magnetic resonance imaging (MRI). The biological effects depend on how much of the energy
P

 

 


Radio and
television
Non-ionizing Ionizing
Cellular radio
Frequency (Hz)
Energy (eV)
Microwaves Infrared Ultraviolet
Visible
light
Radio-frequencies
X-rays Gamma rays
Figure 1: Electromagnetic spectrum from the Federal Communications Commission (FCC), OET
Bulletin 56, 1999.
Review Article Biology and Medicine, 4 (4): 202–216, 2012
BMID: BM-8 204
is absorbed in the body of a living organism, not
just what exists in space. Absorption of RF-EMF
radiations depend on frequency of transmission, power density, distance from the radiating
source and the organism’s size, shape, mineral,
and water content. Exposure will be lower from
towers under most circumstances than from
cell phones because the transmitter is placed
directly against the head during cell phone use
whereas proximity to a cell tower will be an
ambient exposure at a distance (Levitt and Lai,
2010). Exposure guidelines for RF protection
had adopted the value of 4 W/kg averaged over
the whole body (SARWB) as the threshold for the
induction of adverse thermal effects associated
with an increase of the body core temperature
of about 1C in animal experiments. This standard is set by International Commission on Nonionizing Radiation Protection (ICNIRP), national
Radiological Protection Board (NRPB), and
Institute of Electrical and Electronics Engineers
(IEEE) (Barnes and Greenebaum, 2007).
Cell Phones and Cell Tower Standards in India
India has adopted ICNIRP guidelines as the
standard for safety limits of exposure to radiofrequency energy produced by mobile handsets
for general public as follows: whole-body average SAR of 0.08 W/kg, localized SAR for head
and trunk of 2 W/kg, and localized SAR for limbs
4 W/kg. The basic restrictions/proper limits for
power density specified in ICNIRP guidelines for
safe frequencies between 400 and 2000 MHz,
adopted in India, for occupational exposure is
22.5 W/m2
, and general public is 4.5 W/m2
for
900 MHz (ICNIRP, 1998).
Antennas of cell tower transmit in the
frequency range of 869–890 MHz for CDMA,
935–960 MHz for GSM-900, 1805–1880 MHz for
GSM-1800, and 2110–2170 MHz for 3G. Wi-Fi
frequency range is 2.4 GHz, WiMAX is 2.5–3.3
GHz, and 4G LTE is 2.99 GHz. The antennas for
cellular transmissions are typically located on
towers mounted on terraces of houses, apartments or other elevated structures including
rooftops and the sides of buildings, and also
as a freestanding tower. Typical heights for cell
towers are 50–200 feet. Sector antennas for 2G
and 3G transmission, broader sector antennas
for 4G transmission, and parabolic microwave
antennas for point-to-point communications
are used in urban and suburban areas (Table 1).
There are different types of base stations used
by operators in India and they include the macro
cell, micro cell, or pico cell. Categorization is
based on the purpose of the site rather than in
terms of technical constraints such as radiated
power or antenna height. In India, macro cellular
base station provide the main infrastructure for
a mobile phone network and their antennas are
mounted at sufficient height to give them a clear
view over the surrounding geographical area.
The maximum power for individual macro cellular base station transmitter is 20 W. According to
FCC (1999), depending on the cell tower height,
the majority of cellular base stations in urban
and suburban areas operate at an effective radiated power (ERP) of 100 W per channel or less.
ERP is a quantity that takes into consideration
transmitter power and antenna directivity. An
ERP of 100 W corresponds to an actual radiated
power of about 5–10 W, depending on the type
of antenna used. In urban areas, an ERP of 10 W
per channel (corresponding to a radiated power
of 0.5–1 W) or less is commonly used. In India,
cell tower sites transmit hundreds of watts of
power with antenna gain of 50, so ERP sometimes equals 5000 W (Kumar, 2010).
For installation of mobile towers, the
standing advisory committee on radio frequency
Table 1: Radio-frequency sources in India.
RF source Operating frequency Transmission powers Numbers
AM towers 540–1600 kHz 100 KW 197 towers
FM towers 88–108 MHz 10 KW 503 towers
TV towers 180–220 MHz 40 KW 1201 towers
Cell towers 800, 900, 1800 MHz 20 W 5.4 lakh towers
Mobile phones GSM-1800/CDMA
GSM-900
1 W
2 W
800 million
Wi-Fi 2.4–2.5 GHz 10–100 mW Wi-Fi hot spots
Review Article Biology and Medicine, 4 (4): 202–216, 2012
BMID: BM-8 205
allocations (SACFA) clearances are issued by the
wireless monitoring organization, Department of
Telecommunications (DoT), after getting no objection from defence and airport authority considering aviation hazards, obstruction to line of sight
of existing/planned networks and interferences.
In many metros in India, there is no restriction on
the location of the towers leading to a situation of
overlapping of towers, where even more than 30
cell towers can be seen within 1 km2
.
As mobile technology progresses, the
data demands on mobile network increases,
coupled with lower costs, their use has increased
dramatically and the overall levels of exposure of
the population as a whole has increased drastically. Table 2 gives the reference levels for general
public exposure adopted by various countries
and organizations.
Impacts on Biosystem and Ecosystem
Every living being is tuned into the earth’s
electromagnetism and uses it for various purposes. A natural mineral magnetite, which is
found in living tissues, seems to play an important role. These magnetite crystals are found in
bacteria, protozoa, teeth of sea mollusks, fish
and sea mammals, eye and beak of birds, and
in humans. They are also found in the ethmoid
bone above the eye and sinuses and blood-brain
barrier (Warnke, 2007). Migratory birds rarely get
lost, but sometimes there are disruptions due to
storms and magnetic disturbances caused by
man (Kirschvink et al., 2001). The traditional and
most effective approach to study cause–effect
relationships in biological sciences is by experimentation with cells and organisms. The areas
of enquiry and experimentation of in vitro studies include genotoxicity, cancer-related gene and
protein expression, cell proliferation and differentiation, and apoptosis and in vivo studies include
thermal effects, animal behavior, brain biochemistry, neuropathology, teratogenicity, reproduction
and development, immune function, blood-brain
barrier, visual auditory systems and effects on
genetic material, cell function, and biochemistry
(Repacholi and Cardis, 2002). In human health
studies, concerns have been expressed about
the possible interactions of RF-EMF with several
human organ systems such as nervous, circulatory, reproductive, and endocrine systems. In
order to reveal the global effects of RF-EMF on
gene and protein expression, transcriptomics,
Table 2: Reference levels for the general public.
Power density (W/m2
)
900 MHz 1800 MHz
ICNIRP, 1998, adopted by India 4.5 9
FCC, 1999 6 10
IEEE, USA, 1999 6 12
Australia 2 2
Belgium 1.1 2.4
Italy 1 1
Israel x 1
New Zealand x 0.5
China x 0.4
Russia x 0.2
Hungary 0.1 0.1
Toronto Board of Health, Canada, 1999 0.06 0.1
Switzerland 0.04 0.1
France x 0.1
Germany, ECOLOG, 1998 x 0.09
Austria’s precautionary limit 0.001 0.001
Standards Country/organization
Review Article Biology and Medicine, 4 (4): 202–216, 2012
BMID: BM-8 206
and proteomics as high-throughput screening
techniques (HTSTs), were eventually employed in
EMF research with an intention to screen potential EMF responsive genes and/or proteins without any bias (Nylund and Leszczynski, 2004).
The safety standards set by ICNIRP, adopted by
India, has only taken into account the short-term
effects and not against the biological effects from
long-term, non-thermal, low-level microwave
exposure from mobile phones, cell phone towers, and many other wireless devices.
Current Research
Various studies have shown that even at low
levels of this radiation, there is evidence of damage to cell tissue and DNA, and it has been linked
to brain tumors, cancer, suppressed immune
function, neuroendocrine disruption, chronic
fatigue syndrome, and depression (Rogers, 2002;
Milham, 2010). Oncogenesis studies at molecular and cellular levels due to RF-EMF radiations
are considered particularly important (Marino
and Carrubba, 2009). Orientation, navigation,
and homing are critical traits expressed by
organisms ranging from bacteria through higher
vertebrates. Across many species and groups of
organisms, compelling evidence exists that the
physical basis of this response is tiny crystals
of single-domain magnetite (Fe3
O4
) (Kirschvink
et al., 2001). All magnetic field sensitivity in living organisms, including elasmobranch fishes,
is the result of a highly evolved, finely-tuned
sensory system based on single-domain, ferromagnetic crystals. Animals that depend on the
natural electrical, magnetic, and electromagnetic
fields for their orientation and navigation through
earth’s atmosphere are confused by the much
stronger and constantly changing artificial fields
created by technology and fail to navigate back
to their home environments (Warnke, 2007).
Studies on Plants
Tops of trees tend to dry up when they directly
face the cell tower antennas and they seem to
be most vulnerable if they have their roots close
to the water (Belyavskaya, 2004). They also have
a gloomy and unhealthy appearance, possible
growth delays, and a higher tendency to contract plagues and illnesses. According to Levitt
(2010), trees, algae, and other vegetation may
also be affected by RF-EMF. Some studies have
found both growth stimulation and dieback.
The browning of tree tops is often observed
near cell towers, especially when water is near
their root base. The tree tops are known as RF
waveguides. In fact, military applications utilize
this capability in trees for low-flying weapon systems. In an observational study, it was found that
the output of most fruit-bearing trees reduced
drastically from 100% to 5% after 2.5 years of
cell tower installation in a farm facing four cell
towers in Gurgaon–Delhi Toll Naka (Kumar and
Kumar, 2009).
Studies on Insects
Monarch butterflies and locusts migrate great
distances using their antennae to sense air currents and earths electromagnetic fields. Moths
are drawn to light frequencies. Ants, with the help
of their antennas are adept at electrical transmission and found to respond to frequencies as low
as 9 MHz. Flying ants are very sensitive to electromagnetic fields (Warnke, 2007).
Bees have clusters of magnetite in the
abdominal areas. Colony collapse disorder (CCD)
was observed in beehives exposed to 900 MHz
for 10 minutes, with sudden disappearance of
a hive’s inhabitants, leaving only queen, eggs,
and a few immature workers behind. With navigational skills affected, worker bees stopped
coming to the hives after 10 days and egg production in queen bees dropped drastically to
100 eggs/day compared to 350 eggs (Sharma and
Kumar, 2010). Radiation affects the pollinators,
honeybees, whose numbers have recently been
declining due to CCD by 60% at US West Coast
apiaries and 70% along the East Coast (Cane
and Tepedino, 2001). CCD is being documented
in Greece, Italy, Germany, Portugal, Spain, and
Switzerland. Studies performed in Europe documented navigational disorientation, lower honey
production, and decreased bee survivorship
(Kimmel et al., 2007). EMFs from telecommunication infrastructure interfere with bees’ biological
clocks that enable them to compensate properly
for the sun’s movements, as a result of which,
may fly in the wrong direction when attempting
to return to the hive (Rubin et al., 2006). Bee colonies irradiated with digital enhanced cordless
communications (DECT) phones and mobile
handsets had a dramatic impact on the behavior of the bees, namely by inducing the worker
Review Article Biology and Medicine, 4 (4): 202–216, 2012
BMID: BM-8 207
piping signal. In natural conditions, worker piping either announces the swarming process of
the bee colony or is a signal of a disturbed bee
colony (Favre, 2011).
A study by the University of Athens on
fruit flies exposed to 6 minutes of 900 MHz pulsed
radiation for 5 days showed reduction in reproductive capacity (Panagopoulos et al., 2004).
Likewise in 2007, in both 900 and 1800 MHz,
similar changes in reproductive capacity with no
significant difference between the two frequencies were observed (Panagopoulos et al., 2007).
In a third study, it was found it was due degeneration of large numbers of egg chambers after
DNA fragmentation (Panagopoulos et al., 2010).
When Drosophila melanogaster adult insects
were exposed to the radiation of a GSM 900/1800
mobile phone antenna at different distances ranging from 0 to 100 cm, these radiations decreased
the reproductive capacity by cell death induction
at all distances tested (Levengood, 1969).
Studies on Amphibians and Reptiles
Salamanders and turtles have navigational abilities based on magnetic sensing as well as smell.
Many species of frogs have disappeared all
over the world in the last 3–5 years. Amphibians
can be especially sensitive because their skin
is always moist, and they live close to, or in
water, which conducts electricity easily (Hotary
and Robinson, 1994). Toads when exposed to
1425 MHz at a power density of 0.6 mW/cm2
developed arrhythmia (Levitina, 1966). Increased
mortality and induced deformities were noted
in frog tadpoles (Rana temporaria) (Levengood,
1969). It was observed that experimental tadpoles developed more slowly, less synchronously than control tadpoles, remain at the early
stages for a longer time, developed allergies and
that EMF causes changes in the blood counts
(Grefner et al., 1998). In a two-month study in
Spain in common frog tadpoles on the effects
of mobile phone mast located at a distance of
140 m noted low coordination of movements,
an asynchronous growth, resulting in both big
and small tadpoles, and a high mortality (90%)
in exposed group. For the unexposed group in
Faraday cage, the coordination of movements
was normal, the development was synchronous,
and a mortality of 4.2% was obtained (Balmori,
2009). In the eggs and embryos of Rana sylvatica
and Ambystoma maculatum abnormalities at
several developmental stages were noted such
as microcephalia, scoliosis, edema, and retarded
growth. Tadpoles developed severe leg malformations and extra legs, as well as a pronounced
alteration of histogenesis which took the form of
subepidermal blistering and edema. Effects were
noted in reproduction, circulatory, and central
nervous system, general health and well being
(Balmori, 2010; Balmori, 2005).
Studies on Birds
A study by the Centre for Environment and
Vocational Studies of Punjab University noted that
embryos of 50 eggs of house sparrows were damaged after being exposed to mobile tower radiation for 5–30 minutes (MOEF, 2010). Observed
changes included reproductive and coordination
problems and aggressiveness. Tower-emitted
microwave radiation affected bird breeding, nesting, and roosting in Valladolid, Spain (US Fish &
Wildlife Service, 2009). House sparrows, white
storks, rock doves, magpies, collared doves
exhibited nest and site abandonment, plumage
deterioration (lack of shine, beardless rachis, etc.),
locomotion problems, and even death among
some birds. No symptoms were observed prior to
construction of the cell phone towers. According
to Balmori, plumage deterioration and damaged
feather are the first signs of weakening, illnesses,
or stress in birds. The disappearance of insects,
leading to lack of food, could have an influence
on bird’s weakening, especially at the first stages
in young bird’s life. In chick embryos exposed to
ELF pulsed EMR, a potent teratogenic effect was
observed, leading to microphthalmia, abnormal
trunkal torsion, and malformations on the neural
tube (Lahijani and Ghafoori, 2000).
White storks were heavily impacted by
the tower radiation during the 2002–2004 nesting season in Spain. Evidence of a connection between sparrow decline in UK and the
introduction of phone mast GSM was established (Balmori, 2009). In a study in Spain, the
effects of mobile phone mast has been noted
in house sparrow (Passer domesticus), white
stork (Ciconia ciconia), reporting problems with
reproduction, circulatory, and central nervous
system, general health and well-being (microwave syndrome) (Balmori, 2009). Deformities
and deaths were noted in the domestic chicken
embryos subjected to low-level, non-thermal
radiation from the standard 915 MHz cell phone
Review Article Biology and Medicine, 4 (4): 202–216, 2012
BMID: BM-8 208
frequency under laboratory conditions (US Fish &
Wildlife Service, 2009). Neural responses of
Zebra Finches to 900 MHz radiation under laboratory conditions showed that 76% of the
neurons responded by 3.5 times more firings
(Beason and Semm, 2002). Eye, beak, and brain
tissues of birds are loaded with magnetite, sensitive to magnetic fields, interferes with navigation
(Mouritsen and Ritz, 2005).
Studies on Mammals
In a survey of two berry farms in similar habitats
in Western Massachusetts (Doyon, 2008), one
with no cell phone towers, there were abundant
signs of wildlife, migrating and resident birds,
bats, small and large mammals, and insects
including bees and the other farm with a cellphone tower located adjacent to the berry patch,
virtually no signs of wildlife, tracks, scat, or
feathers were noted. The berries on bushes were
uneaten by birds and insects and the berries
that fell to the ground were uneaten by animals.
Whole body irradiation of 20 rats and 15 rabbits
at 9.3 GHz for 20 minutes revealed statistically
significant changes in cardiac activity (Repacholi
et al., 1998). Bradycardia developed in 30% of
the cases. Separate ventricular extra systoles
also developed. In a study on cows and calves
on the effects of exposure from mobile phone
base stations, it was noted that 32% of calves
developed nuclear cataracts, 3.6% severely.
Oxidative stress was increased in the eyes with
cataracts, and there was an association between
oxidative stress and the distance to the nearest
mast (Hässig et al., 2009). It was found that at
a GSM signal of 915 MHz, all standard modulations included, output power level in pulses
2 W, specific absorption rate (SAR) 0.4 mW/g
exposure for 2 hours, 11 genes were up-regulated and one down-regulated, hence affected
expression of genes in rat brain cells (Belyaev
et al., 2006). The induced genes encode proteins
with diverse functions including neurotransmitter
regulation, blood-brain barrier (BBB), and melatonin production.
When rats were exposed for 2 hours
a day for 45 days at 0.21 mW/cm2
power density SAR (0.038 W/kg), a significant decrease in
melatonin and increase in both creatine kinase
and caspase 3 was found (Kesari et al., 2011).
This shows that chronic exposure to these
radiations may be an indication of possible
tumor promotion. A study on pregnant rats and
brains of fetal rats was carried out after irradiating them with different intensities of microwave
radiation from cellular phones for 20 days three
times a day. Superoxide dismutase (SOD), glutathione peroxidase (GSH-Px), malondialdehyde (MDA), noradrenaline (NE), dopamine (DA),
and 5-hydroxyindoleacetic acid (5-HIAA) in the
brain were assayed. The significant content differences of noradrenaline and dopamine were
found in fetal rat brains (Jing et al., 2012). A
study in rabbits exposed to continuous wave and
pulsed power at 5.5 GHz found acute effects in
the eyes, where lens opacities developed within
4 days (Birenbaum et al., 1969).
Behavioral tasks, including the morris
water maze (MWM), radial arm maze, and object
recognition task have been extensively used to test
cognitive impairment following exposure of rodents
to mobile phone radiation (GSM 900 MHz) on various frequencies and SAR values (Fragopoulou
et al., 2010). Exposed animals in most of the cases
revealed defects in their working memory possibly due to cholinergic pathway distraction. Mobile
phone RF-EMF exposure significantly altered the
passive avoidance behavior and hippocampal
morphology in rats (Narayanan et al., 2010).
With regards to DNA damage or cell
death induction due to microwave exposure, in
a series of early experiments, rats were exposed
to pulsed and continuous-wave 2450 MHz radiation for 2 hours at an average power density
of 2 mW/cm2
and their brain cells were subsequently examined for DNA breaks by comet
assay. The authors found a dose-dependent
(0.6 and 1.2 W/kg whole body SAR) increase in
DNA single-strand and double-strand breaks,
4 hours after the exposure to either the pulsed
or the continuous-wave radiation. The same
authors found that melatonin and PBN (N-tertbutyl-alpha-phenylnitrone) both known free radical scavengers, block the above effect of DNA
damage by the microwave radiation (Lai and
Singh, 1995, 1996, 1997). Death in domestic animals like hamsters and guinea pigs were noted
(Balmori, 2003). Bats use electromagnetic sensors in different frequencies. Since 1998, a study
on a free-tailed bat colony, having Tadarida
teniotis and Pipistrellus pipistrellus has been carried out in Spain and a decrease in number of
bats were noted with several phone masts 80 m
from the colony. A dead specimen of Myotis
myotis was found near a small antenna in the city
centre (Balmori, 2009).
Review Article Biology and Medicine, 4 (4): 202–216, 2012
BMID: BM-8 209
The most affected of the species are
bees, birds, and bats and without these pollinators visiting flowers, 33% of fruits and vegetables would not exist, and as the number of
pollinators decline, the agricultural crops will fall
short and the price of groceries will go up (Kevan
and Phillips, 2001).
Studies on Humans
The exposure to continuous RF-EMF radiation
poses a greater risk to children, particularly due
to their thinner skulls and rapid rate of growth.
Also at risk are the elderly, the frail, and pregnant women (Cherry, 2001). DNA damage via
free radical formation inside cells has also been
recorded (Lai and Singh, 1996). Free radicals
kill cells by damaging macromolecules such as
DNA, protein, and membrane are carcinogenic.
In fact, EMR enhances free radical activity.
Single- and double-strand DNA breaks are seen
in rat brain cells after acute exposure to radiofrequency electromagnetic radiation. Kane (2001)
denotes that RF-EMF radiations lead to tissue
damage, DNA damage, or chromosome mutations. In 2008, the Austrian Department of Health
found a higher risk of cancer among people living
within 200 m of a mobile phone base station and
that cancer risk rose with increasing exposure,
reaching 8.5 times the norm for people most
exposed. From a study on in vitro cell response
to mobile phone radiation (900 MHz GSM signal) using two variants of human endothelial cell
line, it was suggested that the cell response to
mobile phone radiation might be genome- and
proteome-dependent. Therefore, it is likely that
different types of cells and from different species might respond differently to mobile phone
radiation or might have different sensitivity to this
weak stimulus (Nylund and Leszczynski, 2006).
The results of the Interphone, an international case–control study to assess the brain
tumor risk in relation to mobile telephone use,
reveals no overall increase in risk of glioma or
meningioma but there were suggestions of an
increased risk of glioma at the highest exposure
levels (30 minutes per day of cell phone use for
8–10 years) and ipsilateral exposures (ICNIRP,
2011). Children and young adults were excluded
from the study and a separate study called MobiKids is underway. According to Santini et al.
(2002), comparisons of complaints in relation
with distance from base station show significant
increase as compared to people living greater
than 300 m or not exposed to base station, till
300 m for tiredness, 200 m for headache, sleep
disturbance, and discomfort, and 100 m for irritability, depression, loss of memory, dizziness, and
libido decrease. Women significantly more often
than men complained of headache, nausea, loss
of appetite, sleep disturbance, depression, discomfort, and visual perturbations (Santini et al.,
2002). According to Oberfeld et al. (2004) in Spain,
a follow-up study found that the most exposed
people had a higher incidence of fatigue, irritability, headaches, nausea, loss of appetite, sleeping disorders, depression, discomfort, difficulties
concentrating, memory loss, visual disorders,
dizziness, and cardiovascular problems. Women
are more at risk as they tend to spend more time
at home and are exposed to radiation continuously. The authors recommended a maximum
exposure of 0.0001 ∝W/cm2
or 0.000001 W/m2
.
There was prevalence of neuropsychiatric complaints among people living near base stations
(Abdel-Rassoul et al., 2007). Urban electromagnetic contamination (electrosmog) 900 and
1800 MHz pulsated waves interfere in the nervous
system of living beings (Hyland, 2000). Growing
amounts of published research show adverse
effects on both humans and wildlife far below a
thermal threshold, usually referred to as “non-thermal effects”, especially under conditions of longterm, low-level exposure (Levitt and Lai, 2010).
Australian research conducted by De
Iuliis et al. (2009) by subjecting in vitro samples of human spermatozoa to radio-frequency
radiation at 1.8 GHz and SAR of 0.4–27.5 W/kg
showed a correlation between increasing SAR and
decreased motility and vitality in sperm, increased
oxidative stress and 8-Oxo-2-deoxyguanosine
markers, stimulating DNA base adduct formation
and increased DNA fragmentation. GSM mobile
phone exposure can activate cellular stress
response in both humans and animal cells and
cause the cells to produce heat shock proteins
(HSP27 and HSP70) (Leszczynski, 2002). HSPs
inhibit natural programmed cell death (apoptosis),
whereby cells that should have committed suicide
continue to live. Recent studies have shown that
these HSPs inhibit apoptosis in cancer cells. In
several cases, melatonin hormone which controls
the daily biological cycle and has an oncostatic
action, produced by the epiphysis (pineal gland)
in mammals, mainly during the night, is found to
reduce the action of EMR exposure, but the synthesis of melatonin itself seems to be reduced
Review Article Biology and Medicine, 4 (4): 202–216, 2012
BMID: BM-8 210
by EMR (Panagopoulos et al., 2008). In a study
to observe the effects of melatonin in hormone
balance in a diabetic, it was found that melatonin
caused reduction in serum insulin, serum cortisol,
serum ACTH, and serum TSH levels while increase
in serum gastrin level. Of the biochemical parameters, melatonin caused reductions in TLC, LDLC,
and FBS while increase in HDLC. It also caused
reduction in neutrophil and increase in lymphocyte
count in a diabetic with increase in faecal fat excretion (Mitra and Bhattacharya, 2008).
RF-EMR produces DNA damage via
free radical formation inside cells. Free radicals
kill cells by damaging macromolecules such as
DNA, protein, and membrane, also shown to be
carcinogenic. EMR enhances free radical activity.
EMR interferes with navigational equipments, lifeline electronic gadgets in hospitals, and affects
patients with pacemakers. A short-term exposure (15 and 30 minutes) to RFR (900 MHz) from
a mobile phone caused a significant increase
in DNA single strand breaks in human hair root
cells located around the ear which is used for the
phone calls (Çam and Seyhan, 2012). Various in
vitro studies have shown that 1800 MHz RF-EMF
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 (Xu et al., 2010).
Studies carried out on the RF levels
in North India, particularly at the mobile tower
sites at Delhi have shown that people in Indian
cities are exposed to dangerously high levels
of EMF pollution (Tanwar, 2006). An independent study was commissioned by the Cellular
Operators Association of India (COAI) and
Association of Unified Telecom Service Providers
of India (AUSPI) as a proactive measure stemming from the concern for the public health
and safety issues on electromagnetic radiation
measurement at New Delhi showed compliance
with ICNIRP standards. 180 areas were studied across the capital to understand the extent
of RF-EMF radiations emitting from the mobile
towers, revealed that the readings were 100
times below international safety guidelines. The
study measured cumulative emissions within the
800–2000 MHz band of frequency (which includes
both GSM and CDMA technologies) across in the
nation’s capital using carefully calibrated equipment, as per the DoT prescribed procedure in line
with the ICNIRP specifications. In a similar, but
independent case study in Mumbai, it was found
that people living within 50–300 m radius are in
the high radiation zone and are more prone to illeffects of electromagnetic radiation. Four cases of
cancer were found in three consecutive floors (6th,
7th, 8th) directly facing and at similar height as
four mobile phone towers placed at the roof of the
opposite building (Kumar, 2010). According to the
Seletun Scientific Statement (2011), low-intensity
(non-thermal) bioeffects and adverse health effects
are demonstrated at levels significantly below
existing exposure standards. ICNIRP/WHO and
IEEE/FCC public safety limits are inadequate and
obsolete with respect to prolonged, low-intensity
exposures (New International EMF Alliance, 2011).
New, biologically-based public exposure standards are urgently needed to protect public health
world-wide. EMR exposures should be reduced
now rather than waiting for proof of harm before
acting (Fragopoulou et al., 2010).
Electrohypersensitivity (EHS) and
Electromagnetic Field Intolerance (EFI)
Syndrome
Electrosensitivity of people is now recognized
as a physical impairment by government health
authorities in the United Kingdom and Sweden.
The UK Health Protection Agency (HPA) recognized that people can suffer nausea, headaches,
and muscle pains when exposed to electromagnetic fields from mobile phones, electricity pylons,
and computer screens. A case study in Sweden,
one of the first countries where mobile technology was introduced approximately 15 years ago,
shows that 250,000 Swedes are allergic to mobile
phone radiation. Sweden has now recognized
EHS as a physical degradation and EHS sufferers are entitled to have metal shielding installed in
their homes free of charge from the local government (Kumar, 2010; Johansson, 2010).
Belpomme (2011) in his presentation at
the 8th National Congress on Electrosmog in
Berne in 2011 elaborates on the dangers of wireless technology and the diagnostics and treatment of the electromagnetic field intolerance (EFI)
Syndrome. In his study from 2008 to 2011, the
patients with EHS were investigated with a pulse
equilibrium brain scan, dosage of histamine in the
blood, dosage of the heat shock proteins HSP70
and HSP27, and appearance and disappearance
of symptoms on exposure to an electromagnetic
field source. Diagnosis of fatigue and depression were noted. The physiological changes
such as vitamin D deficiency, decrease in heat
Review Article Biology and Medicine, 4 (4): 202–216, 2012
BMID: BM-8 211
shock proteins, increase in histamines, increase
in biomarker of the opening of blood-brain barrier, protein S100P, decrease in urinary melatonin,
and increase in blood anti-myelin proteins were
noted in the electrosensitives. Around 50% of the
patients in the study had used a mobile phone for
more than one hour per day during several years
and his findings were similar to the figures published by Hardell’s study (2007) dealing with the
cancer occurrences and electromagnetic fields.
Future Challenges and Solutions
Research into the advantages of radio-frequency
energies seen in tissue heating in benign prostatic hyperplasia (BPH), electrical therapy for cardiac arrhythmia, radio-frequency ablation, use of
41.5–44.5C temperature to kill tumors, shortwave
and microwave diathermy for musculoskeletal injuries, and microwave oven used in food preparation
are all carried out under controlled conditions. But
effects, if any, from RF-EMF radiations released
into the environment over a long period of time in
densely populated areas where people are continuously exposed to them will show in years to
come. According to Osepchuk (1983), frequencies
used in industrial, scientific, and medical heating
processes are 27.12, 40.68, 433, 915, 2450, and
5800 MHz. Out of which, for diathermy, frequencies used are 27.12, 915, and 2450 MHz in US and
433 MHz is authorized in Europe. According to
Kasevich (2000), “the physics of electromagnetic
waves and their interactions with material and biological systems is based on the concept that the
electromagnetic wave is a force field which exerts
a mechanical torque, pressure or force on electrically charged molecules. All living things contain
these dielectric properties. The thermal effects
produced by absorption of electromagnetic
energy are the direct result of water molecules
acted upon by the oscillating electric field, rubbing against each other to produce electric heat
(thermal effects)”. Research work on electromagnetic bioeffects in humans and animals in the nonthermal range is continuing where effects are noted
even at intensities lower than 1 mW/m2
(0.001 W/m2
or 1000 ∝W/m2
, 0.0001 mW/cm2
or 0.1 ∝W/cm2
).
According to Levitt (2007), adverse outcomes of pregnancy can be mutagenic, teratogenic, oncogenic or carcinogenic, and ionizing
radiations can cause all three. In animal studies,
non-ionizing radiation was also found to be teratogenic and oncogenic, and likely mutagenic, but
it is unclear if these observations were due to
heating affect, non-thermal affects or both. Trees,
plants, soil, grass, and shrubs have the ability
to absorb electromagnetic wave energy over a
very broad range of wavelengths. According to
the resonance concept, human beings can act as
receiving antennas for some frequencies, where
the absorbed energy is maximized in some areas
of the body, like the brain (Levitt, 2007).
In the Bioinitiative Report, a document
prepared by 14 international experts in a ninemonth project, in which over 2000 scientific studies
were reviewed, Sage (2007) came to a conclusion
that there may be no lower limit that may be safe,
and there was a need for biologically-based limits (1 mW/m2
or 0.001 W/m2
) and children are at
most risk. Safety limits suggested are 0.001 W/m2
for outdoor cumulative radio-frequency exposure
and 0.0001 W/m2
for indoor, cumulative radiofrequency exposure. According to Blank (2012),
there is a need for a realistic biological standard to
replace the thermal (SAR) standard. The precautionary approaches includes prudence avoidance
for public and ALARA, which stands for “as low
as reasonably attainable” for regulatory agencies.
According to Havas (2006), several disorders, including asthma, ADD/ADHD, diabetes,
multiple sclerosis, chronic fatigue, bromyalgia,
are increasing at an alarming rate, as is electromagnetic pollution in the form of dirty electricity,
ground current, and radio-frequency radiation
from wireless devices and the connection between
electromagnetic pollution and these disorders
needs to be investigated and the percentage of
people sensitive to this form of energy needs to
be determined. According to Milham (2010), 20th
century epidemic of the so-called diseases of civilization, including cardiovascular disease, cancer,
diabetes, and also suicides, was caused by electrification and the unique biological responses
we have to it and that our evolutionary balance,
developed over the millennia has been severely
disturbed and disrupted by man-made EMFs.
Conclusion
The Department of Telecommunication (DoT) in
India has set new norms for cell phone towers
with effect from September 1, 2012 (The Hindu,
2012). Exposure standards for RF-EMF radiation has been reduced to one-tenth of the existing level and SAR from 2 to 1.6 W/kg. This came
after the Ministry of Environment and Forests
Review Article Biology and Medicine, 4 (4): 202–216, 2012
BMID: BM-8 212
(MOEF) set up an Inter-Ministerial Committee
(IMC) to study the effects of RF-EMF radiations
on wildlife (Figure 2) and concluded that out
of the 919 research papers collected on birds,
bees, plants, other animals, and humans, 593
showed impacts, 180 showed no impacts, and
196 were inconclusive studies. They conclude
that there are no long-term data available on the
environmental impacts of RF-EMF radiations in
India. The population of India is increasing as
well as the cell phone subscribers and the cell
towers as supporting infrastructure. Hence, there
is an urgent need to fill the gaps and do further
research in this field with emphasis on the effects
of early life and prenatal RF-EMF radiation exposure in animals, dosimetry studies, cellular studies using more sensitive methods, and human
epidemiological studies, especially on children
and young adults on behavioral and neurological
disorders and cancer. Meanwhile, one can take
the precautionary principle approach and reduce
RF-EMF radiation effects of cell phone towers by
relocating towers away from densely populated
areas, increasing height of towers or changing
the direction of the antenna.
References
Abdel-Rassoul G, El-Fateh OA, Salem MA, Michael A,
Farahat F, EI-Batanouny M, et al., 2007. Neurobehavioral
effects among inhabitants around mobile phone base
stations. Neurotoxicology, 28(2): 434–440.
ARPANSA, 2011. Introduction to radiation basics.
http://www.arpansa.gov.au/RadiationProtection/
basics/index.cfm
Balmori A, 2003. The effects of microwave radiation
on the wildlife. Preliminary results, Valladolid (Spain).
http://www.whale.to/b/martinez.pdf
Balmori A, 2005. Possible effects of electromagnetic
 elds from phone masts on a population of white
stork (Ciconia ciconia). Electromagnetic Biology and
Medicine, 24: 109–119.
Balmori A, 2009. Electromagnetic pollution from phone
masts. Effects on wildlife. Pathophysiology, 16(2):
191–199. DOI: 10.1016/j.pathophys.2009.01.007
Balmori A, 2010. Mobile phone masts effects on
common frog (Rana temporaria) tadpoles: the city
turned into a laboratory. Electromagnetic Biology and
Medicine, 29: 31–35.
Barnes FS, Greenebaum B, 2007. Handbook of biological
effects of electromagnetic  elds: bioengineering and
biophysical aspects of electromagnetic  elds. 3rd
Edition, Boca Raton, FL: CRC Taylor and Francis
Press, 440.
Beason RC, Semm P, 2002. Responses of neurons
to an amplitude modulated microwave stimulus.
Neuroscience Letters, 333: 175–178.
Belpomme D, 2011. Presentation of Prof. Dominique
Belpomme at 8th National Congress on Electrosmog,
Berne. http://citizensforsafetechnology.org/uploads/
scribd/Presentation%20of%20Prof.pdf
Human
Other animals
Plants
Wildlife
Bees
Birds
0%
Impact No impact Inconclusive
10% 20% 30% 40% 50% 60% 70% 80% 90% 100%
Figure 2: Percentage of studies that reported harmful effect of EMR in various groups of organisms
(n  919), MOEF Report (2010).
Review Article Biology and Medicine, 4 (4): 202–216, 2012
BMID: BM-8 213
Belyaev IY, Koch CB, Terenius O, Roxström-Lindquist K,
Malmgren LO, Sommer W, et al., 2006. Exposure
of rat brain to 915 MHz GSM microwaves induces
changes in gene expression but not double stranded
DNA breaks or effects on chromatin conformation.
Bioelectromagnetics, 27(4): 295–306.
Belyavskaya NA, 2004. Biological effects due to
weak magnetic  eld on plants. Advances in Space
Research, 34(7): 1566–1574.
Birenbaum L, Grosof GM, Rosenthal SW, Zaret
MM, 1969. Effect of microwaves on the eye. IEEE
Transactions on Biomedical Engineering, 16(1): 7–14.
Blank M, 2012. Cell Towers and Cancer – Bioinitiative
Report. http://www.youtube.com/watch?va6wLFeIr
CtU&featurerelated; www.weepinitiative.org
Business Standard, 2010. Cellular tower study
debunks radiation myth by COAI, AUSPI. December
21, 2010. http://www.business-standard.com/india/
news/cellular-tower-study-debunks-radiation-mythby-coai-auspi/419036
Çam ST, Seyhan N, 2012. Single -strand DNA breaks
in human hair root cells exposed to mobile phone
radiation. International Journal of Radiation Biology,
88(5): 420–424.
Cane JH, Tepedino VJ, 2001. Causes and extent of
declines among native North American invertebrate
pollinators: detection, evidence, and consequences.
Conservation Ecology, 5(1): 1.
Cherry N, 2001. Evidence that electromagnetic
radiation is genotoxic: the implications for the
epidemiology of cancer and cardiac, neurological,
and reproductive effects. http://www.neilcherry.com/
documents/90_m2_EMR_Evidence_That_EMR-EMF_
is_genotoxic.pdf
Davis D, 2010. Disconnect. USA: Dutton Penguin
Group, 69–95.
De Iuliis GN, Newey RJ, King BV, Aitken RJ, 2009.
Mobile phone radiation induces reactive oxygen
species production and DNA damage in human
spermatozoa in vitro. PLoS ONE, 4(7): e6446.
DoT, 2010. Report of the Inter-Ministerial Committee
(IMC) on EMF radiation. Ministry of Communication
and Information Technology, Government of India.
http://www.dot.gov.in/miscellaneous/IMC%20Report/
IMC%20Report.pdf
Doyon PR, 2008. Are the microwaves killing the
insects, frogs, and birds? And are we next? http://
www.thenhf.com/article.php?id480
Favre D, 2011. Mobile phone-induced honeybee worker
piping. Apidologie, 42(3): 270–279. DOI: 10.1007/
s13592-011-0016-x
FCC, 1999. Questions and answers about
biological effects and potential hazards of radiofrequency electromagnetic fields. OET Bulletin 56,
4th Edition. http://www.fcc.gov/encyclopedia/oetbulletins-line
Fragopoulou A, Grigoriev Y, Johansson O, Margaritis LH,
Morgan L, Richter E, et al., 2010. Scienti c panel
on electromagnetic  eld health risks: consensus
points, recommendations, and rationales. Reviews on
Environmental Health, 25(4): 307–317.
Grefner NM, Yakovleva TL, Boreysha IK, 1998. Effects
of electromagnetic radiation on tadpole development
in the common frog (Rana temporaria L.). Russian
Journal of Ecology, 29(2): 133–134.
Hardell L, Carlberg M, Söderqvist F, Mild KH, Morgan
LL, 2007. Long-term use of cellular phones and
brain tumours: increased risk associated with use
for  or  10 years. Occupational and Environmental
Medicine, 64(9): 626–632.
Hässig M, Jud F, Naegeli H, Kupper J, Spiess BM,
2009. Prevalence of nuclear cataract in Swiss veal
calves and its possible association with mobile
telephone antenna base stations. Schweizer Archiv fur
Tierheilkde, 151(10): 471–478.
Havas M, 2006. Electromagnetic hypersensitivity:
biological effects of dirty electricity with emphasis
on diabetes and multiple sclerosis. Electromagnetic
Biology and Medicine, 25: 259–268.
Hotary KB, Robinson KR, 1994. Endogenous
electrical currents and voltage gradients in Xenopus
embryos and the consequences of their disruption.
Developmental Biology, 166: 789–800.
Hyland GJ, 2000. Physics and biology of mobile
telephony. The Lancet, 356: 1833–1836.
ICNIRP SCI Review, 2011. Mobile phones, brain
tumors, and the Interphone study: Where are we
now? Environmental Health Perspectives, 119(11):
1534–1538.
ICNIRP, 1998. Guidelines for limiting exposure to
time-varying electric, magnetic, and electromagnetic
 elds (up to 300 GHz). Health Physics, 74(4):
494–522.
Instituto Edumed, 2010. Latin American experts
committee on high frequency electromagnetic  elds
and human health, Non-ionizing electromagnetic
Review Article Biology and Medicine, 4 (4): 202–216, 2012
BMID: BM-8 214
radiation in the radio-frequency spectrum and its effects
on human health. www.edumed.org.br/lasr2008/en/
Jing J, Yuhua Z, Xiao-qian Y, Rongping J, Dong-mei G,
Xi C, 2012. The in uence of microwave radiation from
cellular phone on fetal rat brain. Electromagnetic
Biology and Medicine, 31(1): 57–66.
Johansson O, 2010. Aspects of studies on the
functional impairment electrohypersensitivity. IOP
Conference Series: Earth and Environmental Science,
10: 012005. DOI:10.1088/1755-1315/10/1/012005
Kane RC, 2001. Cellular telephone russian roulette –
a historical and scienti c perspective. New York:
Vantage Press.
Kasevich RS, 2000. Cell Towers, Wireless Convenience
or Environmental Hazards? Proceedings of the “Cell
Towers Forum” State of the Science/State of the Law.
Chapter 11, Levitt BB (Ed.), Canada: New Century
Publishing, pp. 170–175.
Kesari KK, Kumar S, Behari J, 2011. Biomarkers
inducing changes due to microwave exposure
effect on rat brain, pp. 1–4. http://www.academia.
edu/967270/Biomarkers_inducing_changes_due_to_
microwave_exposure_effect_on_rat_brain
Kevan PG, Phillips TP, 2001. The economic impacts
of pollinator declines: an approach to assessing the
consequences. Ecology and Society, 5(1): 8.
Kimmel S, Kuhn J, Harst W, Stever H, 2007. Effects
of electromagnetic exposition on the behavior of the
honeybee (Apis mellifera). Environmental Systems
Research, 8: 1–8.
Kirschvink JL, Walker MM, Diebel CE, 2001.
Magnetite-based magnetoreception. Current Opinion
in Neurobiology, 11: 462–467.
Kumar G, 2010. Report on cell tower radiation, submitted to
the Secretary, DoT, Delhi. http://www.ee.iitb.ac.in/~mwave/
GK-cell-tower-rad-report-DOT-Dec2010.pdf
Kumar N, Kumar G, 2009. Biological effects of cell
tower radiation on human body. Electrical engineering
department, IIT Bombay. December 16–19, ISMOT,
2009, New Delhi, India.
Lahijani MS, Ghafoori M, 2000. Teratogenic effects of
sinusoidal extremely low frequency electromagnetic
fields on morphology of 24 hr chick embryos.
Indian Journal of Experimental Biology, 38(7):
692–699.
Lai H, Singh NP, 1995. Acute low-intensity microwave
exposure increases DNA single-strand breaks in rat
brain cells. Bioelectromagnetics, 16: 207–210.
Lai H, Singh NP, 1996. Single- and double-strand DNA
breaks in rat brain cells after acute exposure to radiofrequency electromagnetic radiation. International
Journal of Radiation Biology, 69: 513–521.
Lai H, Singh NP, 1997. Melatonin and a spin-trap
compound block radio-frequency electromagnetic
radiation-induced DNA strand breaks in rat brain cells.
Bioelectromagnetics, 18: 446–454.
Leszczynski D, Joenväärä S, Reivinen J, Kuokka R,
2002. Non-thermal activation of the hsp27/p38MAPK
stress pathway by mobile phone radiation in human
endothelial cells: molecular mechanism for cancerand blood-brain barrier–related effects. Differentiation,
70: 120–129.
Levengood WC, 1969. A new teratogenic agent
applied to amphibian embryos. Journal of Embryology
and Experimental Morphology, 21(1): 23–31.
Levitina NA, 1966. Non-thermal effect of microwaves
on the rhythm of cardiac contractions in the frog.
Bulletin of Experimental Biology and Medicine, 62(12):
64–66.
Levitt BB, 2007. Electromagnetic  elds: a consumer’s
guide to the issues and how to protect ourselves.
Authors Guild Backinprint.com Edition, iUniverse, Inc.
ISBN: 978-0-595-47607-7.
Levitt BB, 2010. The environmental effects of wireless
technologies and other sources of non-ionizing
radiation: an overview. http://www.croww.org/
environmental-effects.pdf
Levitt BB, Lai H, 2010. Biological effects from exposure
to electromagnetic radiation emitted by cell tower
base stations and other antenna arrays. Canada: NRC
Research Press, 369–395.
Marino AA, Carrubba A, 2009. The effects of mobile
phone electromagnetic  elds on brain electrical activity:
A critical review of literature. Electromagnetic Biology
and Medicine, 28(3): 250-274. http://andrewamarino.
com/PDFs/CellphoneEMFs-Review.pdf
Milham S, 2010. Historical evidence that electri cation
caused the 20th century epidemic of disease of
civilization. Medical Hypotheses, 74(2): 337–345.
Mitra A, Bhattacharya D, 2008. Effects of melatonin in
mild diabetics with dyslipidaemia. Journal of Human
Ecology, 23(2): 109–114.
MOEF, 2010. Report on possible impacts of communication towers on wildlife, including birds and
bees, Government of India. http://www.
indiaenvironmentportal.org.in/ les/ le/ nal_mobile_
towers_report.pdf
Review Article Biology and Medicine, 4 (4): 202–216, 2012
BMID: BM-8 215
Mouritsen H, Ritz T, 2005. Magnetoreception and its
use in bird navigation. Current Opinion in Neurobiology,
15(4): 406–414.
Narayanan SN, Kumar RS, Potu BK, Nayak S,
Bhat PG, Mailankot M, 2010. Effect of radio-frequency
electromagnetic radiations (RF-EMR) on passive avoidance behaviour and hippocampal morphology in Wistar
rats. Uppsala Journal of Medical Sciences, 115: 91–96.
New International EMF Alliance, 2011. Seletun
Statement, Oslo, Norway. http://iemfa.org/index.php/
publications/seletun-resolution
Nylund R, Leszczynski D, 2004. Proteomics analysis
of human endothelial cell line EA.hy926 after exposure
to GSM 900 radiation. Proteomics, 4: 1359–1365.
Nylund R, Leszczynski D, 2006. Mobile phone radiation
causes changes in gene and protein expression in
human endothelial cell lines and the response seems
to be genome- and proteome-dependent. Proteomics,
6: 4769–4780.
Oberfeld G, Navarro E, Portoles M, Maestu C, GomezPerretta C, 2004. The microwave syndrome – further
aspects of a Spanish study. EBEA Congres KosGreece, 1: 1–9.
Osepchuk JM, 1983. Biological Effects of
Electromagnetic Radiation. New York, USA: John
Wiley and Sons, IEEE INC.
Panagopoulos DJ, Karabarbounis A, Margaritis LH,
2004. Effect of GSM 900 MHz mobile phone radiation on
the reproductive capacity of Drosophila melanogaster.
Electromagnetic Biology and Medicine, 23(1): 29–43.
Panagopoulos DJ, Karabarbounis A, Margaritis LH,
2008. Mobile Telephony Radiation Effects on Living
Organisms. In: mobile telephones, Chapter 3, Harper
AC, Buress RV (Eds.). New York: Nova Science
Publishers, pp. 107–149.
Panagopoulos DJ, Chavdoula ED, Nezis IP, Margaritis
LH, 2007. Cell death induced by GSM 900 MHz and
DCS 1800 MHz mobile telephony radiation. Mutation
Research, 626(1–2): 69–78.
Panagopoulos DJ, Chavdoula ED, Margaritis LH, 2010.
Bioeffects of mobile telephony radiation in relation to
its intensity or distance from the antenna. International
Journal of Radiation Biology, 86(5): 345–357.
Repacholi MH, Cardis E, 2002. Criteria for EMF health
risk assessment. Radiation Protection Dosimetry,
72: 305–312.
Repacholi MH, Rubtsova NB, Muc AM, 1998. Proceedings
of the International Meeting on “Electromagnetic Fields:
Biological Effects and Hygienic Standardization”,
Moscow. Geneva, Switzerland: World Health Organisation,
1999. http://www.who.int/iris/handle/10665/65976
Rogers KJ, 2002. Health effects from cell phone
tower radiation. http://www.scribd.com/doc/3773284/
Health-Effects-from-Cell-Phone-Tower-Radiation
Rubin EB, Shemesh Y, Cohen M, Elgavish S, Robertson
HM, Bloch G, 2006. Molecular and phylogenetic
analyses reveal mammalian-like clockwork in the
honey bee (Apis mellifera) and shed new light on the
molecular evolution of the circadian clock. Genome
Research, 16(11): 1352–1365.
Sage C, 2007.The Bioinitiative Report and Biologicallybased Exposure Standards. http://www.youtube.com/
watch?vjC6Bzz25rzU&featurerelmfu
Santini R, Santini P, Danze JM, Le Ruz P, Seigne M,
2002. Investigation on the health of people living near
mobile telephone relay stations: incidence according
to distance and sex. Pathological Biology (Paris),
50(6): 369–373.
SCENIHR, 2007. Possible effects of electromagnetic
 elds (EMF) on human health. 16th Plenary on 21st March
2007. http://ec.europa.eu/health/ph_risk/committees/04_
scenihr/docs/scenihr_o_007.pdf
Sharma VP, Kumar NR, 2010. Changes in honeybee
behaviour and biology under the in uence of cellphone
radiations. Current Science, 98(10): 1376–1378.
Tanwar VS, 2006. Living Dangerously in Indian
cities: an RF radiation pollution perspective.
ElectroMagnetic Interference and Compatibility
(INCEMIC), 2006 Proceedings of the 9th International
Conference, Cogent EMR Solutions, New Delhi, India,
pp. 458–466.
The Hindu, 2012. Mobile base station radiation
limit will be cut from September 1. August 27,
2012. http://www.thehindu.com/news/national/
article3828735.ece
The Hindu, 2012. No major health fallout from
typical exposure, say studies. August 28, 2012.
http://www.thehindu.com/todays-paper/tp-national/
article3829594.ece
TRAI, 2012. Indian telecom services performance
indicator report for the quarter ending December.
Information note to the Press. Press release No.
74/2012, New Delhi. www.trai.gov.in
US Fish & Wildlife Service, 2009. Public Press
release on brie ng paper on the need for research
into the cumulative impacts of communication
towers on migratory birds and other wildlife in
Review Article Biology and Medicine, 4 (4): 202–216, 2012
BMID: BM-8 216

 

Medical/biological study (experimental study)
Genotoxicity investigation of ELF-magnetic fields in Salmonella typhimurium with the sensitive SOS-based VITOTOX test. med./bio.


By: Verschaeve L, Anthonissen R, Grudniewska M, Wudarski J, Gevaert L, Maes A


Published in: Bioelectromagnetics 2011; 32 (7): 580-584
Journal PubMed doi:10.1002/bem.20672
Download citation in RIS format
Aim of study (acc. to author)
To study the genotoxicity of extremely low frequency magnetic fields alone or in combination with known chemical mutagens using a sensitive test system (VITOTOX test) with Salmonella typhimurium.

Background/further details
The effect of magnetic field exposure alone and in combination with the three well-known mutagens 4-NQO (0.04 and 0.4 µg/ml), bleomycin (0.125 and 1.25 µg/ml) and benzpyrene (80 and 800 µg/ml), and the non-DNA-reactive chemical resorcinol (whose mutagenicity is questionable; 0.1 and 1 µg/ml) was investigated.

Endpoint
genotoxicity/mutation: genotoxic response of Salmonella typhimurium
Exposure
50/60 Hz magnetic field low frequency
co-exposure
Exposure Parameters
Exposure 1: 50 Hz
Exposure duration: continuous for 1 or 2 h
magnetic flux density: 100 µT
magnetic flux density: 500 µT
Exposed system:
bacterium
Salmonella typhimurium/TA-104-recN2-4 (with luciferase gene and recN promoter: produces light when DNA is damaged) & TA104-pr1 (with lux gene under a constitutive promoter: light production not influenced by genotoxic compounds (internal control))
Methods
Endpoint/measurement parameters/methodology
genotoxicity/mutation: genotoxic response (SOS response) of Salmonella typhimurium (VITOTOX test: light emission measurement every 5 min. for 4 h)
Investigated system: bacterium
Time of investigation: after exposure
Main outcome of study (acc. to author)
The data showed that extremely low frequency magnetic fields did not induce SOS response-based mutagenicity in Salmonella typhimurium bacteria and did not show any synergistic effect when combined with chemical mutagens.

Study character: medical/biological study experimental study full/main study Brief Communication
Study funded by
not stated/no funding
Related articles
Verschaeve L et al. (2016): Co-exposure of ELF-magnetic fields and chemical mutagens: An investigation of genotoxicity with the SOS-based VITOTOX test in Salmonella typhimurium.
Ruiz-Gomez MJ et al. (2010): No evidence of cellular alterations by MilliTesla-level static and 50 Hz magnetic fields on S. cerevisiae.
Ruiz-Gomez MJ et al. (2010): Effect of 2.45 mT sinusoidal 50 Hz magnetic field on Saccharomyces cerevisiae strains deficient in DNA strand breaks repair.
Vijayalaxmi et al. (2009): Genetic damage in mammalian somatic cells exposed to extremely low frequency electro-magnetic fields: a meta-analysis of data from 87 publications (1990-2007).
Nakasono S et al. (2008): Intermediate frequency magnetic fields do not have mutagenic, co-mutagenic or gene conversion potentials in microbial genotoxicity tests.
Vijayalaxmi et al. (2008): Genetic damage in mammalian somatic cells exposed to radiofrequency radiation: a meta-analysis of data from 63 publications (1990-2005).
Williams PA et al. (2006): 14.6 mT ELF magnetic field exposure yields no DNA breaks in model system Salmonella, but provides evidence of heat stress protection.
Nakasono S et al. (2000): A 50 Hz, 14 mT magnetic field is not mutagenic or co-mutagenic in bacterial mutation assays.
Maes A et al. (2000): Cytogenetic effects of 50 Hz magnetic fields of different magnetic flux densities.
Alipov YD et al. (1994): Systemic reaction of E. coli cells to weak electromagnetic fields of extremely low frequency.