RADIO WAVES ARE HARMFUL, PERIOD! POWER LEVEL IS IRRELEVANT
Just one violin out of tune
in an orchestra, or one voice off-key in a choir, will ruin a beautiful
harmony, or an enchanting ensemble. It matters not how loudly it
grates, or how softly; if it does not stop, the performance will come to
an end.
So
it is with the cells of our bodies, and of the birds, insects, animals
and plants whose music fills the Earth. When a jarring note is
introduced, no matter how softly, chords become discords, melody becomes
noise, life degrades and disappears.
Life, Information, and Electricity
The cohesion of life does not come from chemistry. It comes from the Earth, Sun and stars.
K.H. Li wrote, in his forward to the book, Electromagnetic Bio-Information:
“It
is the informational aspect of biological systems that characterizes
the essential view of life. And this is less reflected by biochemical
findings, but rather by a level beyond the domain of chemical
reactivity, namely that of electromagnetic fields.” [1]
Nikolai Kositsky, Aljona Nizhelska and Grigory Ponezha reviewed 40 years of research in Ukraine and Russia and concluded:
“Biological
effects [of electromagnetic radiation] depend not on the strength of
the energy carried into one or another system, but on the information
carried into it.” [2]
W. Grundler and F. Kaiser wrote:
“Living
cells exhibit a high degree of information processing and
communication... It is clearly demonstrated that a fast oscillating,
very weak outer field is influencing biological reactions of cells... We
have to take into account an ‘internal’ oscillator (the cell itself or
parts of the cell or of its environment) coupling with the outer field.”
[3]
John Zimmerman and Vernon Rogers wrote:
“Electromagnetic
bioinformation depends on the ability of organisms to emit, receive,
and interpret spatiotemporal patterns of electromagnetic fields.” [4]
Herbert L. König, a student of Winfried Schumann, wrote:
“Electromagnetic
forces in general must play a role of an as yet incalculable importance
in the information transfer between or to living organisms.” [5]
Ulrich Warnke wrote:
“The
communicative form of antennae contact in bees and ants can be
registered by an oscillograph. Every time a short contact occurs between
the antennae a signal is generated in the electrolyte system of the
recipient in the form of an impulse.” [6]
Günther Becker
showed that the rate of gallery building by termites was affected by
the existence of termites in an adjoining container, but not if the wall
between them was shielded with a conductive material. “These results
indicate that communication among termite groups is based on either
electric or electromagnetic fields produced by the insects,” he wrote.
[7]
Bernhard Ruth
wrote that the growth of plants and animals cannot be explained in
terms of chemical reactions because “all chemical reactions occur
equally in all directions” and biological growth is directional. “The
existing cells of an organism have to determine when and where a new
cell is to be generated by mitosis. This can only be achieved by means
of an information transfer which stimulates the required cell to divide,
and which is not emitted in all directions homogenously.” [8]
Helmut A. Fischer wrote:
“There
is good reason for believing that, in addition to mechanical and
chemical forms of communication, there are more biophysical ways of
communication... The findings made so far confirm that the biochemical
processes in a cell, besides thermic effects, also elicit other
electromagnetic signals." [9]
Igor Jerman wrote:
“Coherent
electromagnetic oscillations in cells permit ordered intermolecular
processes and highly selective attractions between enzymes and
substrates. These oscillations... represent an important means of
intercellular long-range connection and thus have an important role in
maintaining an intercellular order... Neoplasms follow from the fact
that some of the cells within the organism escape from the intercellular
coherent field and thus from the intercellular order.” [10]
Living cells emit signals
throughout the electromagnetic spectrum
In their study, “Electromagnetic emission at micron wavelengths from active nerves,” Allan Fraser and Allan Frey measured infrared emissions from nerves with wavelengths between 2 and 20 microns, at a strength of 6 μW/cm2. [11]
Bernhard Ruth detected light photons emitted by plants:
“The
light intensity emitted by seedlings of wheat, beans, lentils and corn
varied between 700 cps (counts per second) and 250 cps... The spectral
distribution extended from 400 nm to 600 nm... Yeast cells show a
radiation of between 150 and 380 nm.” [8]
Shou Sin-Sung wrote that “DNA is a possible radiation source.” [12]
A.H. Jafary-Asl and Cyril W. Smith detected radio frequency signals from yeast at a frequency of 8 MHz. [13]
Herbert A. Pohl detected signals at 7 and 33 kHz from a species of algae. [14]
J. Kent Pollock and Douglas G. Pohl
in dielectrophoresis studies detected RF emissions from mouse cells at
frequencies between 4 and 9 MHz. Similar emissions were detected from
cells from bacteria, yeast, worms, chickens, frogs, monkeys, and humans.
Maximum emissions occurred during cell division, and no emissions from
dead cells:
“The
evidence from the m-DEP experiments and from the closely related
pattern experiments consistently indicate that cells are producing radio
frequency electric fields.” [15]
Sergey Sit’ko
and his colleagues measured emissions from the human body between 37-78
GHz at 0.000000000000001 to 0.0000000000000001 μW/cm2Hz. [16]
It takes little or no power to interfere with life
Allan Frey wrote:
“Electromagnetic
fields are not a foreign substance to living beings like lead or
cyanide. With foreign substances, the greater the dose, the greater the
effect -- a dose-response relationship. Rather, living beings are
electrochemical systems that use very low frequency EMFs in everything
from protein folding through cellular communication to nervous system
function. To model how EMFs affect living beings, one might compare them
to the radio we use to listen to music.
“The
EMF signal the radio detects and transduces into the sound of music is
almost unmeasurably weak. At the same time, there are, in toto,
strong EMFs impinging on the radio. We don’t notice the stronger EMF
signals because they are not the appropriate frequency or modulation.
Thus, they don’t disturb the music we hear. However, if you impose on
the radio an appropriately tuned EMF or harmonic, even if it is very
weak, it will interfere with the music. Similarly, if you impose a very
weak EMF signal on a living being, it has the possibility of interfering
with normal function if it is properly tuned. That is the model that
much biological data and theory tell us to use, not a toxicological
model.” [17]
Gerard Hyland said:
“The
human body is an electrochemical instrument of exquisite sensitivity.”
[18] “If a signal can operate a mechanical device, it can disturb every
cell in the human body.” [19]
Igor Belyaev wrote:
“While
the dose rate/SAR concept is adequate for description of acute thermal
effects, it is not applicable for chronic exposures to N[on]T[hermal]
M[icro]W[aves].” [20] and ”The 51.755 GHz resonance frequency of the
cell reaction to MMWs did not depend on power density (PD) in the range
from 10(exp-19) to 3 × 10(exp-3) W/cm2.” [21]
Ross Adey, at Loma Linda University, wrote:
“We
have discovered some of the keys to understanding how body cells
‘whisper’ to to one another, and, in so doing we have discovered some of
the keys to understanding how electromagnetic fields, so weak that some
scientists have regarded them as incapable of biological effects, are
detected by living tissues, and we have studied some of the likely
consequences for human health... These fields can exert effects even at
intensities near zero, in other words, a lower limit or threshold may
not exist.” [22]
Neil Cherry
presented “conclusive evidence” that “the safe level of exposure is
zero” [23] and that radio signals “can interfere with hearts, brains and
cells at extremely low intensities.” [24]
Robert Becker wrote:
“There
is no effective way to shield yourself from environmental fields except
to avoid areas where they are prevalent” [25] and “If the system’s
sensitivity is as presently described, then frequency becomes a more
important parameter in any experiment than field strength.” [26]
In The Body Electric, he wrote:
“The
accumulated research has clearly shown that small doses often have the
same effects as larger ones... Indeed there has already been one report
of brain wave changes suggesting resonance of neural electrical currents
with radio waves and microwaves down to a billionth of a microwatt...
We must understand that no amount of artificial EMR, no matter how
small, has been proven safe for continuous exposure. Bioeffects have
been found at the lowest measurable doses.” [27]
Herbert L. König wrote:
“Biological systems have sensitivity values of the same order of magnitude as the field intensity values of natural fields.” [5]
William Bise
testified before the U.S. Senate about effects on brain waves that he
elicited by radio waves at near-zero intensity. The results of his
experiments ought to terrify every person who ever uses a cell phone and
every doctor who is confronted with the extraordinary amount of anxiety
and depression in his or her patients today, because the radiation in
Bise’s experiments, at exposure levels 10,000,000,000 to
100,000,000,000,000 times lower than a cell phone, had strong and
instantaneous effects on all subjects’ brain waves and mental states:
“A
pilot study was conducted on five men and five women volunteers... They
ranged in age from 18 to 48 years. Three had been occupationally
exposed to RF energy; the other seven had not and all were in apparent
good health. The RF ranges covered from .1 to 960 Mhz C[ontinuous]
W[ave] and 8.5 to 9.6 Ghz pulse modulated. Power levels were varied from
10(exp-16) wt/cm2 to 10(exp-12) wt/cm2... Experimental time for each
volunteer was typically 50 minutes...
“Subjects'
EEG traces displayed desynchronized alpha waves of 15 to 25 percent
higher than normal amplitude and slow waves appeared at certain
radiofrequencies. Conversely, diminution and desynchronization of alpha
wave amplitude on the order of 20 to 50 percent occurred at other
radiofrequencies and 2 to 6 Hz slow waves appeared. These two anomalous
patterns were found in both men and women volunteers. Mental attitudes
appeared to change during the tests. CW frequencies at a power density
of about 10(exp-15) wt/cm2 which produced EEG changes in males, were
found between 130 and 780 Mhz. Female volunteers’ EEG alterations
occurred between 350 and 960 Mhz. Pulse modulation tests on two males,
at a power density of about 10(exp-12) wt/cm2 showed EEG changes around
9.1 and 9.15 Ghz. Brain waves changed almost immediately upon tuning a
generator to a frequency which produced them and then almost immediately
reverted to their normal patterns when the generator frequency was
altered or turned off.” [28]
Sheldon Meyers, Director of the U.S. Environmental Protection Agency’s Office of Radiation Programs, told Congress that “it is not possible to assign a low intensity limit or threshold below which the exposures are without effect.” [29]
Reba Goodman and Martin Blank wrote:
“Induction
of the stress response by magnetic fields occurs at 14 orders of
magnitude lower energy density than with thermal stimuli, the current
benchmark for cell phone safety standards.” [30]
Yury Shckorbatov found evidence of cell damage after only one second of exposure to 18.75 GHz microwaves at a level of 0.2 mW/cm2. [31]
Low power can be more harmful than high power
Andrew Wood, Rohan Mate and Ken Karipidis reviewed 107 experimental studies and found that a lower exposure level tended to have a greater biological effect, and the difference was highly significant (p < 0.001). [32]
Stefano Cucurachi et al. reviewed 113 peer-reviewed field and laboratory studies and found that RF radiation with the lowest power tended to cause the greatest ecological damage. [33]
Maria Sadchikova found
that among people occupationally exposed to RF radiation in the 1950s,
1960s and 1970s, the sickest were those exposed to the lowest, not the highest levels. [34], [35]
Abraham Lilienfeld
analyzed the health of Moscow embassy employees during the 1950s, 1960s
and 1970s at a time when Russia was continuously irradiating the
embassy with microwaves. His report was written for the U.S. Department
of State. Table 6.32 of his report shows that male employees exposed to
the lowest level of radiation had the most symptoms in 18 of 20 symptom categories. [36] They had more:
depression
migraine
lassitude
irritability
nervous disorders
anxiety
vibrations
intraocular pain
sensations
loss of appetite
difficulty concentrating
memory loss
dizziness
finger tremor
hallucinations
insomnia
neurosis
other symptoms
Liliya M. Fatkhoutdinova studied
the effects of video display terminals on blood pressure. Lower levels
of electromagnetic fields raised blood pressure more than higher levels.
[37]
Vladimir N. Binhi and Robert J. Goldman studied the proliferation of wound cells in response to electric fields. They wrote:
“Most
dramatic is the fact that relatively intense electric fields sometimes
do not cause appreciable effect while smaller fields do.” [38]
Herbert L. König wrote:
“Exceptionally intense fields often cause no reaction at all.” [5]
Leif Salford, Bertil Persson, Arne Brun, Henrietta Nittby
and their team at Lund University in Sweden researched the effects of
RF radiation on the blood-brain barrier for 20 years. They found that
the lowest levels of exposure caused the most damage to the
blood-brain barrier. [39] They calculated that you will do more damage
to your brain if you hold a cell phone one meter away from you than if
you hold it up to your head. [40]
Dimitris Panagopoulos found
that RF radiation reduced reproduction in fruit flies. The maximum
impact on fruit fly reproduction occurred when the source of radiation
was at some distance away from the flies. [41]
Igor Belyaev, experimenting on E. coli,
found that genetic effects occurred at specific frequencies and that
the magnitude of the effect did not change with power level over 16
orders of magnitude, all the way down to 0.000000000001 μW/cm2. [21]
Numerous scientists in many laboratories -- Carl Blackman et al. at the U.S. Environmental Protection Agency [42]; Suzanne M. Bawin, Leonard K. Kaczmarek and W. Ross Adey [43]; Sisir K. Dutta et al. [44]; Jean-Louis Schwartz, Dennis E. House and Geoffrey A. R. Mealing [45]; and Kumud K. Kunjilwar and Jitendra Behari
[46] -- found that calcium depletion from brain and heart cells
occurred at specific frequencies and exposure levels and did not
increase with power. Dutta found a 3,000-fold decrease in power caused a 4-fold increase in calcium exiting from cells.
W. Grundler and F. Kaiser
halved the growth rate of yeast at a precise microwave frequency. The
magnitude of the effect of this frequency did not change with intensity
over several orders of magnitude, down to 5 pW/cm2. [3]
Cooking Your Brain and Your DNA
Here
are some other findings that should terrify anyone who uses a cell
phone, considering the unprecedented numbers of young people today with
cancers and neurological diseases.
First are some measurements made by Markus Antonietti, Director of the
Max Planck Institute of Colloids and Interfaces in Germany. In 2006,
when cell phone use was becoming universal, he wondered what they might
be doing to the brain. Cell phones exposed the brain to about 1 W/kg
SAR, which did not heat the whole brain by more than one degree Celsius,
but what about the conditions that exist in the tiny synapses, the
junctions between neurons where nerve impulses are transmitted from one
nerve cell to another? His research team decided to simulate the
conditions between cell membranes with tiny fat droplets in salt water.
[47] “Ions accumulate on these,” reported Zeit Online, the
newspaper that interviewed him, “and by changing the salt concentration
and the droplet size, the conditions of biological tissue can be
simulated, i.e. a kind of concentrated liquid brain.
“‘And
now comes the tragedy,’ said the Max Planck Director. ‘Exactly where we
are closest to the conditions in the brain, we see the strongest
heating.’ Temperature peaks of 100 degrees. He had expected warming, but
not to this extent. ‘There is a hundred times as much energy absorbed
as previously thought. That is a horror.’” [48]
It
turns out a cell phone not only boils your synapses, but also your DNA.
A number of research teams have discovered that DNA is a good conductor
and so, as in the synapses, RF radiation is conducted and amplified
tremendously in DNA.
Jacqueline K. Barton
and her colleagues at the California Institute of Technology in
Pasadena observed ultrafast electron transfer in DNA over large
distances. [49] “In effect,” she told Science News, “DNA acts like a molecular wire.” [50]
Hans-Werner Fink and Christian Schönenberger
reported that the conductivity of DNA is 105 Siemens per meter, which
is ten times larger than that of most electrically conducting polymers,
and about one-tenth the conductivity of mercury. [51]
Charles Polk
tells us what the consequences of this are. Based on Fink and
Schönenberger’s measurements, Polk calculated that the rate of
temperature increase in the interior of DNA exposed to a cell phone at 1
W/kg SAR is 60 degrees Celsius per second! [52].
Your
cell phone, if you still use one, is cooking your brain and damaging
it, during every second that you use it. The cell towers that it
commands are sickening us, no matter how far away from one we manage to
be. The satellites -- 9,500 of them and increasing rapidly -- are
polluting our bodies, sterilizing our planet, and severing our
connection to our sources of vitality, beneath our feet, in the air, in
the oceans, and in the heavens.
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