Which is the electromagnetic field component causing the long term

Which is the electromagnetic field component
causing the long term health (chronic) effects?
A possible explanation, theory, detection
G. A. FLOREA
A. DINCA
I. RODEAN
E. MATEESCU
Planck’s Principle
A new scientific truth does not triumph by convincing its
opponents and making them to see the light, but rather
because its opponents eventually die and a new generation
grows up that is familiarly with it.
Max Planck ( 1858- 1947 )
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GENERAL CONSIDERATIONS
Whether in as much as the electric field is concerned it was concluded by the international
scientific community since the 90’s that there are no direct biological effects, only physiological
effects caused by densities of the currents higher than 2 mA/sq.m. induced into the human body.
A different situation is met when considering the impact of the magnetic component of the
electromagnetic field of industrial frequency.
The maximal values recommended for the magnetic flux density in professional and residential
exposure situations have been established by international and national organizations. ICNIRP,
IEEE and the European Community propose the limit of 100μT and 500 μT for the residential
exposure and the quasi-permanent professional exposure, respectively; these limits have been
determined starting from the physiologic effect of the magnetic field based on a maximum density
of current induced into the human body of 2 mA/sq.m., under the conditions of different safety
factors for the two types of exposure. Higher values of the limit may be accepted in the case of a
short time professional exposure. The mentioned limits are considered valid for most countries, as
resulted from the Eurelectric synthesis [1, 2].
However, the impact of the magnetic field is not only instantaneously, but long term biologically,
too, inducing the development of some diseases or the aggravation of some anterior diseases in
the case of exposure to relatively low values of the magnetic flux density. Thus, as resulting from
the conclusions of California Health Report – June 2002 [3] in situations of exposure to very low
values of the magnetic flux density ranked between 0.2 and 1.2 μT, a decrease of the immune
capacity of the human body occurs due to the decrease in melatonin secretion.
An EU conducted « The Reflex study »[4] investigated the effects of radiation on animal and
human cells in laboratory conditions confirmed that even the weakest electric and electromagnetic
fields have a biological impact. There were detected breaks in DNA chains in specimens exposed
to fields with one hundred thousands lower intensities than the maximum allowable ones.
From the newer ELF- EMF studies (2007- 2012) [5] resulted that 81% (35 studies) show effects
and 19% (8 studies) do not show effects. The genotoxic effects of radiofrequency radiation and of
ELF- EMF appear very similar, an explanation being that “DNA appears to possess the two
structural characteristics of fractal antennas, electronic conduction and self symmetry”, showing:.
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There have to be mentioned the countries where much lower maximum levels of
magnetic flux denisties are mandatory, i.e.[1] :
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increased risk of genetic damage among electrical workers ;
50 Hz magnetic field affect chromatin conformation and 53 BP1 foci in human lymphocytes ;
ELF-EMF a mild oxidative stressor and DNA damage inducer ;
Significant induction of cytogenetic damage in peripheral lymphocytes of electrical workers ;
DNA double strand breaks in human lens epithelial cells in vitro for longer duration.
Brasil- sao Paolo- 3 µT for new , 10 µT for old facilities;
Costa Rica 15 µT;
Israel 1 µT;
Italy- 3 µT new, 10 µT old;
The Netherlands 0.4 µT long duration children;
Norway 0.4 µT homes and children new;
Slovenia – 10 µT,
Swiss 1 µT.
Six significant effects or mechanisms of ELF radiation upon human health were
identified through initial research on this topic, including but not limited to [6]:
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human mental functioning, influence and control
disruption of cellular metabolism,
suppression of the immune system,
genetic modification and/or NA effects,
influence upon free radical formation,
cyclotronic resonance
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WHICH IS THE DANGEROUS COMPONENT OF THE ELECTROMAGNETIC FIELD ?
Since the long term effects of the magnetic field on melatonin secretion were seen at very low
magnetic induction (under 1.2 μT) and the uncoupling of the signal transduction from melatonin
receptors adenylyl cyclase was observed at 1.2 μT as well as 100 μT [7], we have to ask
ourselves if the magnetic field is the real cause of such effects. The electric field being already out
of question, it seems that is something else guilty for the health effects. The only answer can be
THE LONGITUDINAL (SCALAR) component of the electromagnetic field.
The electromagnetic waves are transverse waves. They consist of coupled electric and magnetic
fields. During EM-wave propagation, the respective field vectors oscillate perpendicular to the
direction of energy transfer. They may be measured by instruments and their frequencies,
measured in Hertz and are the basis of today’s entire high frequency technology. But these waves
contain another kind of wave, which was discovered as early as1890 by Nikola Tesla in Colorado
Springs, Colorado, USA, and are named after him (Tesla waves). In quantum physics these
waves can be called longitudinal waves or scalar waves.
These scalar waves always coexist with the transverse waves. While the transverse waves are
spreading from the origin in a circular shape, the longitudinal waves, which are familiar from the
study of sound, are spreading as impulse or compression waves in a longitudinal direction. They
are very different from the transverse waves and follow different laws. They can be modulated in
frequency as well as in wavelength, allowing the transfer of the informations in a much higher
volume and much more quickly.
As it is known, nature always seeks to work with the optimal method, i.e. not with transverse
waves, but with longitudinal waves. They are utilized as the mechanism of communication needed
by the body to manage the vast amount of information and data to which it is exposed. In the
body, nothing can occure without information and energy transfer, whether cell division, healing
processes or brain or neuronal activity.
The human body biological radiation is identical with Tesla radiation. Our cells and our brain
communicate via scalar waves. Therefore, it can be understood that the body’s communication
and control system would be severely impacted if this transfer mechanism is impacted, resulting
possible errors in cell division, protein synthesis, etc [4].
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Due to the increasing electromagnetic overload of the environment, the cells in organisms are
continually inundated with EM signals of varying intensity. This electromagnetic “noise”
overpowers the cell’s bio-photon field and leads to errors in the harmonious functioning of the
body.
If the influence of these fields is of short duration and low magnitude the cells may repair the error.
If the exposure is of longer duration, the internal cell repair mechanism fatigues and malfunction
occurs.
Also, Dr. Glen Reinfrom from Stanford University Medical Center, USA [8] writes « Although
numerous studies indicate the biological significance of linear, transverse EM and acoustic waves,
relatively little is known about the role of non-linear, non-Hertzian waves in biological systems.
Such a role for non-Hertzian waves is likely since recent quantum mechanical analysis of
biological processes has revealed the inherent non-linearity. Thus contrary to traditional
thermodynamic theories, biochemical reactions can occur far from equilibrium and are not always
dispersive and degenerative. Based on non- linear mathematical analyses of Schrodinger's EM
equations, quantum mechanical models have been developed which describe subatmonic quasiparticles like excitons and plasmons and solitons. Recently it has been proposed that these
quantum particles store and carry biological information along helical macromolecules like DNA. It
has also been suggested that they are generated and propagated along helical proteins in the cell
membrane in response to weak EM radiation in the visible and extremely low frequency
spectrum. »
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THE SCALAR FIELD, THE NEW BUT THE OLD EMF COMPONENT
The complete set of J.C.Maxwell equations was described by the author in 1865, using 20
variables. The original form of these equations was the quaternion one. The practical application
of the quaternion formed equations was quite impossible at that time due to the mathematical
difficultiesof their solving [9]. Later, O.Heaviside and J.W.Gibbs reduced the Maxwell’s equation
system to a much smaller vectorial/scalar equations with 6 field components only [10, 11, 12, 13].
A general quaternion has a scalar (real) and a vector (imaginary) part.
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Q = a + ib + jc + kd
Here a, b, c and d are real numbers and i, j, k are the so-called HAMILTON‘ian unit vectors
They fulfill the equations
i2 = j2 = k2 = ijk = -1
and
ij = k jk = i ki = j
ij = - ji jk = - kj ki = - ik
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Beneath the new notation, the magnetic potential field W and the magnetic mass m was
mentioned here the first time. By calculating the gradient of this magnetic potential field it is
possible to get the magnetic field (or in analogy the magnetostatic field. Maxwell has introduced
this two new field variables into the force equation.
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It is very interesting that Maxwell‘s first formulation of a magnetic charge density and the related
discussion about the possible existence of magnetic monopoles became forgotten for more than
half a century until in 1931 Paul André Maurice DIRAC] again speculated about magnetic
monopoles.
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Prof. Konstantin Meyl (Germany)
The Maxwell equations in any case only describe transverse waves, for which the field pointers
oscillate perpendicular to the direction of propagation.
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The vectorial part of the wave equation (derived from the Maxwell equations)
By using the Laplace operator the well-known wave equation, according to the rules of vector
analysis, can be taken apart in two parts: in the vectorial part (rot rot E), which results from the
Maxwell equations and in a scalar part (grad div E), according to which the divergence of a field
pointer is a scalar. We have to ask ourselves, which properties has this wave part, which founds a
scalar wave?
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The scalar part of the wave equation describes longitudinal electric waves (derivation of plasma
waves).
If we derive the field vector from a scalar potential ϕ, then this approach immediately leads to an
inhomogeneous wave equation, which is called plasma wave. Solutions are known, like the
electron plasma waves, which are longitudinal oscillations of the electron density (Langmuir
waves).
So, by the vectorial part interpration of the Maxwell equations, the electromagnetic field was left
without its scalar part, which could be seen in the original quaternion Maxwell equations. Of
course, the mathematical calculations could be done, but by the loss of the scalar component [11,
12, 13, 14]. What is the importance of this loss ? The missing term of the scalar component of the
electromagnetic field.
The official theory of electrodynamics presumed that always this component, named S is nill,
constituting the so said « gauge condition ». But the question was about the physical meaning of
the scalar field S., or better saying which were the observable phenomena connected with,
question without answer at that time. But the experiments of Nikola Tesla starting from the end of
the 19- th century showed the physical relevance of the scalar fields, but no major interess was
granted to. Many other experiments followed, especially during the last time (Wesley and
Monstein, Tzontchev, Chubaikalo and Riverea Juarez, Jan Nasilowski, Peter Graneau) [14].
The generalized equations as proposed by Vlaenderen [12, 13,14] include at this time the field S,
but in special cases S=0, as it was considered in the vectorial Maxwell equations issued by
Heaviside and Gibbs. The expression of S as resulted from the generalized equations is :
S = - ε0μ0 dØ/dt - divA , in Vs/m2
where : ε0 – electric permitivity of the vacuum, F/m ;
μ0 – electric permeability of the vacuum, H/m;
Ø - electric potential, V ;
A- magnetic potential, Vs/m ;
t – time, s.
The first part of S can be associated with high voltage and/or high frequency power systems and
the second part with a source of divergent/convergent currents, similarly of the magnetic field
induction.
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NASA/CR-2005-213749
Advanced Energetics for Aeronautical
Applications: Volume II
David S. Alexander
MSE Technology Applications, Inc., Butte, Montana
ADVANCED ELECTRIC CONCEPTS ................................................................ 41
3.1 Introduction and Overview ............................................................................ 41
3.1.1 Dr. Charles P. Steinmetz's Theories of Electricity....................................... 41
3.1.2 Longitudinal and Transverse Electric Waves ............................................. 42
3.1.3 Scalar Waves.............................................................................................. 42
3.2 Teachings on Electric Phenomena by Dr. Charles P. Steinmetz …................ 42
3.2.1 Introduction.................................................................................................. 42
3.2.2 Dr. Steinmetz's Teaching on Electric Transients ......................................... 43
3.2.3 Dr. Steinmetz's Teaching on the Electric Field............................................. 44
3.3 Differences Between Longitudinal and Transverse Electric Waves................. 46
3.3.1 Introduction.................................................................................................. 46
3.3.2 Definitions.................................................................................................... 47
3.3.3 Wave Propagation Velocity Differences ....................................................... 47
3.3.4 Transverse Waves vs. Longitudinal Waves: Transmission Line
Characteristics....................................................................................................... 48
3.3.5 Unique Characteristics of Longitudinal Electricity ......................................... 48
3.3.6 Demonstration of Tesla's Radiant Energy Patents........................................ 51
3.3.7 Long-Range Longitudinal Wave Transmission ............................................. 53
3.4 Scalar Waves.................................................................................................. 53
3.4.1 Introduction................................................................................................... 53
3.4.2 Dr. Thomas Valone's Writings on Scalar Waves........................................... 54
3.4.3 Dr. Konstantin Meyl's Teachings on Scalar Waves....................................... 57
3.4.4 The Polarization Synchrotron ....................................................................... 62
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DETECTION
Scalar fields are extremely unusual objects of investigation. Since a scalar field is identical to the
transverse spin polarization of the physical vacuum, and a gravitational field is identical to the
longitudinal spin polarization of the physical vacuum [1].
Experiments show that the scalar fields cannot be shielded by natural media, and in this way their
behavior is similar to that of gravitational fields [2]. However, unlike gravitational fields which
cannot be shielded even by artificial materials, the scalar longitudinal component of the
electromagnetic field are shielded by artificial materials possessing orthonormal topology of
structure. In practice, it is possible to screen them with stretched polyethylene film commonly
produced by industry. This film is manufactured in such a manner that the polymers form an
aligned unidirectional structure. The unidirectional orientation of the polymers results in a
molecular spin ordering. And this results in the generation of a collective torsion field. Two
crossed polyethylene films are transparent to light, and are transparent to most of the radiofrequency spectrum. However, they can effectively shield torsion radiation. The aluminum is
another type of material to be used to block the said field due to aluminum’s unique nano-scaled
spin structures.
In experiments with torsion generators, apparently the main difficulty lies in verifying that the
generated radiation actually is the longitudinal component. To confirm the nature of the generated
emission the screening of the transversal electromagnetic field is needed.
It is necessary to emphasize that the longitudinal component can be detected by a variety of
methods. The influence of this field upon a physical material results in the change of a spin state
of only this material, but alterations of the spin state of the physical vacuum can result in changes
to a light beam's polarization angle, and change to the spin state of a substance can result in
alterations of its magnetizability, Hall's coefficient, thermal conduction, and other properties.
Since changes in the spin state of an electrical conductor may result in the alteration of its
electrical resistance, then an elementary torsion field detector can be based upon a comparison
bridge (Wheatstone bridge). This type of detector was first utilized by N.A.Kozyrev , and later by
an academician of the Russian Academy of Sciences M.M.Lavrentiev and others.
Another type of detector is the torsion balance. Torsion balances were employed in experiments
conducted by N.P.Myshkin at the end of the IXX century, and later were employed in the
experiments of N.A.Kozyrev and others
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Based on the ability to change the rate of any physical process, for instance, altering the
oscillation frequency of quartz crystals, another type of detector was developed ( N.A.Kozyrev
and later A.I.Veinik). For example, measuring the electrical resistence of a tungsten wire.
There are many types of detectors created by different scientists and of course different kinds of
approach [15]. Therefore different things very useful in developing detectors were reported by
Hunt, Bedini, Beck, Howonadec, Golden, and others. Golden has a very good scalar
communications detector and several good scalar communications transmitters. One of his typical
detector systems, for example, performs between 20 and 30 dB better for a given power
transmitted than will a normal communication system with high gain antennas. And, since the
detection of scalar involves outfolding the inner energy spectrum of the Whittaker structure, a
direction finder cannot get a direction fix on the signal transmitted via the scalar system.
Beck has certainly demonstrated an extremely sensitive coil of ultrafine wire, that can often
outperform the finest superconductive quantum interference detector (SQUID). The use of
extremely fine wire - and lots of overlaying coils - drastically reduces or blocks the radial
movement of electrons in any one point in the wire in the coil. Since that's the way electron current
actually moves - the movement down the wire is due to drift velocity, and certainly is not the signal
- Beck's coil effectively prevents most of the "external electron bleedoff" from the stabilized scalar
potential. Thus he's able to block most of the external electromagnetics, and thereby retain the
inner part as well. Precisely, his coil is now using gravitons, not photons, to a significant degree.
So the coil as the interaction area of an instrument is able to hold and pass some of the
internalized EM energy that normally escapes into and through the nucleus only. At the output of
the coil, Beck gets EM from this internal component that the SQUID doesn't see because it
doesn't do the escape-blocking in its interaction area. There are other detector schemes, of
course, such as holographic interferometry and : Dea/Faretto, IGA – 1, TCM030, SADAF-08LC,
SEVA [16, 17, 18].
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THE BIOLOGICAL CELL THE LIFE MASTER UNIT
The cell is the unit of all biological life. A human is an assortment of 1013-1014 cells (BNID
102390), plus an enormous complement of 1014 allied microbes, (BNID 102392)[20]. The
identities of these 1013 cells are shared among more than 200 different cell types (BNID 103626,
106155) which perform a staggering variety of different functions. One of the ways to recognize
these diverse cell types is on the basis of their very different shapes (though in some cases, such
as the different types of white blood cells, the distinctions are more subtle and often reflected in
molecular signatures). For example, the leukocytes of the immune system are approximately
spherical in shape while adherent tissue cells on a microscope slide resemble a fried egg with the
nucleus analogous to the yolk. By way of contrast, the neurons connecting our brains to our legs
can reach lengths of over a meter (BNID 104901) but with a width of only about 10 µm.
Mature female oocytes are among the largest cell types with a ≈120 µm diameter. Other large cell
types include muscle fiber cells that merge together to form syncytia where multiple nuclei reside
in one cell and megakaryocytes, bone marrow cells responsible for the production of blood
platelets. Both of these cell types can reach 40 µm in diameter (BNID 105114). Red blood cells,
also known as erythrocytes, are some of the smallest of human cells. These cells have a
characteristic biconcave disk shape with a depression where the nucleus was lost in maturation
and have a corresponding diameter of 7-8 µm (BNID 100509) and a volume of ≈100 µm3 (BNID
101711, 101713).
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CELL STRUCTURE, MEMBRANE AND DNA
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The cell content a mass of biomolecules surrounded by the membrane.
If the artificial membranes are good insulators with a specific conductance of 10-13 Ω-1m-2
(Goldup et al, 1970), the biological cell conductance is higher (several orders), because of the ion
channels and other pores penetrating the membrane [19].
The membrane is very thin with a thickness of about 6 x 10-9 m (two molecules only). The
membrane capacitance is about 10-2 Fm-2 [19]. The membrane is a bilayer structure composed
of phospholipids, sprinkled or embedded with proteins which perform as channels or transporters
across the membrane, or as receptors. The cell membrane is selectively permeable, meaning that
only some molecules can pass the membrane unobstructed, whereas others need to be
transported (possibly unidirectional) if they are the specific type of molecule. Thickness of the
membrane varies from 5 to 10 nm [21].
The research over the last 15 years showed that the outer membrane structure of every cell in the
body is a unique, semi-crystalline matrix. This means that every one of the trillion plus cells in your
body has an ideal resonant frequency, much like a crystal glass that rings its own special note
when struck.
DNA is a macromolecule made of four different monomers. It encodes the architecture and
function of the cells.
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The DNA double helix is constituted by two strands.
The two strands are connected by sequences of four bases.
The most common DNA macromolecule is the B type and is
found in in the cells of the living organisms [22],
There is still a controversy between the conclusions of the
different performed researches concerning the electric
properties of the DNA, some showing low values of the
resistance 100 kΩ to 1 MΩ and other showing high
resistances from 1GΩ to 1000 GΩ. These opposing results
could not be clear explained. Differences could be obtained
due to base sequences, lengths of the DNA, ambient
surrounding, electrode- molecule interface and so on [23].
Recently, many contactless measurements indicate that the
DNA is not a conductor [22].
Fig. 1. a) The DNA double helix structure [22]
b) The schematic of the chemical structure of
the single strand of DNA
INTERCELLULAR COMMUNICATION
Fig. 2. The geometric characteristics of the double
helix DNA [24]
The first known research concerning the role of the
electromagnetic field in living processes was done
by the Russian scientist Gurwitch in 1923 [25]. He
concluded that each cell emits light at a very low
intensity level, but at that time he had not the
technical possibilities to measure it. This was
possible later, in 1970’s, by the German scientist
Fritz Popp, who demonstrated that a common
feature of the living cells is that of photon emission,
of different intensities, from one cell to another one,
by time and by different outside exciting factors.
Further have to be mentioned the results got by the
Russian scientist P. Garjaev who could intercept the
communication messages between two DNA
molecules
and
of
the
Russian
scientist
Kaznacheyev.It was discovered that the biophoton
emission is interrupted by glass screens but not by
the quartz screens, which confirmed the before
detected wave length in the range of UV.
The question arised from the need to understand
how a cell is transmitting read information and
writing it to another one. The electric field is
rectangular to the DNA axis and the magnetic
induction is along this axis, as shown in Fig. 3.
Fig. 3. The left polarized wave [24]
But the DNA-B is double stranded and the stranded are electrically connected through the bases,
resulting a scalar magnetic field along the DNA axis. Because of the helical structure of the vortex field,
the field lines are open, not closed [24], winding the screw forward compared to a circular polarized
wave (Fig. 3).
Based on the detailed dimensions involved in the DNA strands as shown in Fig. 4, it is possible to
calculate the wave length. Prof. K. Meyl used two methods getting a result of 126 nm+/-6 nm. But the
DNA wave has to rotate around the 6 histons, which correspond to 378 nm, or this is the UV wave
length discovered by F. Popp.
Prof. H. Heine found that during the communication the cells build channels in the connective tissue, the
channels collapsing thereafter. The channels have hyperboloid structures [24].
In the presence of a scalar longitudinal wave the cells may come to resonance, getting energy and
informations from other cells or from outside. There are three conditions: the same frequency, different
algebric signs and the same wave shape. Each cell is sending an unic scalar wave to be received by a
complementary cell, by resonance.
Fig. 4. The DNA B main
geometrical parameters and
the electric field along the
strand [24]
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MECHANISMS
Many performed researches were concentrated on the possible interactions of the weak EMF with
the cell membranes, acting as non linear resonators. Dielectric breakdown of the membrane can
occure in specific conditions [26].
The electric barrier of membranes with thickness of 40 Angstroms is 105 V/cm much higher than
the gradients to be achieved with a maximum of 10V/cm [27].
If an electric field is applied to this cell, an accumulation of electrical charges will result at the cell
membrane and consequently a voltage across the membrane. If the membrane voltage exceeds a
critical value, structural changes in the surface membrane occur with transmembrane pore
formation, this process being known as electroporation.. Electric fields required for electroporation
are one to ten kV/cm [28].
The electric field inside the human body is 10-6 and 10-7 less than the field ouside the body and
the membrane conductivity is 5 order of magnitude smaller than that of the extracellular liquid [29].
The body internal electric field is 1mV/m for an external magnetic field induction of 100 μT [30].
Some conclusions could be drawn that each specific biological function within the proteins of DNA
has its own frequency. Since the proteins and the DNA have some conducting properties, the
electrical charges may move through the backbone of the macromolecules, creating the
conditions for the emission of the electromagnetic waves with frequencies depending on the
charge velocities [26]. Low frequency electric and magnetic fields affect the enzyme function in
DNA, but the reaction is accelerated if the enzymes are realtively inactive [31]. Testing the EM
fields action on the electrons in DNA and biochemical reactions resulted in the case of 60 Hz a
positive reaction of NaK- AT pase at a level of 0.2- 0.3 μT [31]. The field was applied in different
macromolecule conditions resulting that the influence is much stronger as the intrinsec chemical
reactions are weak. This conclusion explains why not all the experiments involving replications of
the same kind did not bring the same positive results. Also, resulted that the electrodynamical
forces, even at a very low level of 10-20 N at the low threshold are strong enough to displace
electrons in DNA.
But, in addition to classical EM fields, the subtle energyof the scalar fields may resonates with the
DNA molecules, causing physical changes in their secondary structures (winding and unwinding
of the helix) [32]. It has to be mentioned G. Rein, too, who considers that non Hertzian waves
propagate through the body via the crystalline lattices of the elaborate collagen network [33].
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It may be considered the DNA as a toroidal shape functioning as a fractal antenna allowing DNA
to collect subtle energies (scalar fields) from the environment and converting them into
conventional EM fields. Further these EM fields are converted again into scalar fields to produce
intracellular events at the biochemical level. The theory is based on the geometric shape of the
toroid, which can be thought as composed by a pseudosphere and a catenoid [34].
The DNA interaction with EMF may cover a wide range of frequency, not a certain frequency
only, as an optimal one, due to the fractal antenna properties of the double helix DNA.
The ability of EMF to lead to DNA strand breaks and damage to proteins is similar to the effect of
the ionizing range fields.The discovery of the stress response activated by the EMF indicate the
interaction with the DNA. The stress response is similar to that activated by other potential harmful
means [35].
The brain has its own set of vibrations it used to communicate with itself and the rest of the body.
The Gamma waves are in the range 25- 60 Hz [36].
The average frequency of the healthy human body during the day time is between 62-68 Hz as it
was measured by Bruce Taino of Taino Technology, Washington. Pollutants with lower frequency
are causing the body frequency lowering, creating an environment towards degenaritive diseases
[37].
« The Akimov group have represented the brain as a non-magnetic spin torsion system where it is
simultaneously transmitter and receiver »[38].
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Based on the above assumptions, two mechanisms are proposed :
As G. Rein and M. Blank concluded, the cell DNA acts as a fracta antenna and
convert the enivironment scalar field of 50/60 Hz frequency into transverse field This
transverse field acts further, on the electrons in DNA, leading to biochemical
reactions, especially in the cases when the the intrinsec reactions are weak. The
environmental scalar fields are acting all the times, in the expossure areas and have
the possibility to find the times when the intrinsec reactions are weak.
The 50/60 Hz frequency scalar fields are interacting with the brain waves of low
frequency. The results are further converted into the already mentioned UV scalar
fields, acting further to the other cells of the human body, inducing stresses, which in
certain circumstancies may develop into different types of sickness.