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The cell-biological aspect of the System
So far most of the electromagnetic research on humans culminated in the identification of individual and special frequencies which control and regulate certain biological functions. Only most recent findings of leading cell biologists and physicists open the view for different and very unusual conclusions. The heterogeneous as well as complex nature of each population of specialized cell receptors has as consequence that every different cell type possesses a unique heterogeneous electromagnetic “ID-card”. Until recently, the display of such frequency characteristics was technically not feasible.
Progress in computer technology makes it possible now to store and analyze millions of data via complex oscillations of characteristics with exactly defined frequencies and voltage amplitudes. Over 30 years, the scientist Prof.Dr. Hans Kempe analyzed and characterized the unique electromagnetic frequencies which are contained in the human energy spectrum. With that, it could now also be unequivocally determined that every human cell shows exactly 62 authoritarian, basic frequencies which are by cell division (after fertilization of the egg cell) divided into three blastemas of 20-21-21 frequencies. Each of these 62 basic characteristics contains, on the other hand, millions of exactly time controlled and voltage regulated frequency patterns. The 62 basic frequencies are identical in all humans, their amplitude however is different. The 62 basic frequencies determine and regulate to a crucial extent anatomy and physiology of the human.
The precise determination of these frequencies now enables us to put human cells in a healthy condition by means of a newly developed frequency application using the Genopuls System. From the scientifical standpoint of view, scientists from the braches Cell-biology and Embryology and medical professionals have fund the de-cording of the 62 Frequencies of the human cell structure intrigued enough to speculated about a real possibility of cell performing active proliferation with the input of the GENOPULS System.
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New findings in biology & biophysics
Since Watson and Crick discovered the nature of deoxyribonucleic acid (DNA - carrier of the genetic material), the biomedical science is based on the assumption that the structure, function, and health of an organism is directly or indirectly regulated by its genes. The main reason for this truth “made of ore” is the assumption that the genes are able to control their own function respectively to provoke chemical changes in the nuclear proteins, especially the histones, and to control the function of the DNA. Figuratively, they therefore should be able to switch themselves on and off. At least this is what suggests the knowledge of biochemistry so far considered as certain that grants the genes primary causality in determining and regulating biological functions. Consequently, the traditional medical research raises the genes to the dominating control element over health and disease.
The dogma of the primacy of DNA has been loudly questioned by the most recent research which discovered that it is a completely false assumption to assign genes an ability of “self regulation”. An important article by H.F. Nijhout (Bio Essay, 12/441, 1990) describes how our general concept of “controls” and “programs” has grown to a metaphor or a model and finally became enslaved by the “veracity of the mechanism” - without any fundamental proof.
Nijhout then defines the truth elegantly and conclusively: “When a gene product is needed, not any inherent ability of the gene but a signal from its environment activates the function of this gene.”
If, however, a gene cannot turn on and off itself, it also can be doubted that it can control anything. Most recent research proves that the continued believe in the primacy of DNA is scientifically not tenable anymore. The function of the gene is dependent on the environment as the responsible element in the biology and in the behavior of the organism.
To understand how the environment controls the biological behavior one has to explain the anatomy and physiology of the cell membrane (plasmalemma). The cell membrane forms the “skin” of the cell. The plasmalemma is the most primitive organelle of the cell and at the same time the only common distinctive mark of all living organisms. The cell membrane is so thin (approximately 10 nm) that it only can be made visible under the electron microscope.
The basic structure of the membrane is a semipermeable protective skin which is bordered by 2 layers of phospholipid molecules.
Figure 1
In the lipid double layer of the thin membrane, integral membrane proteins (IMP) are enclosed. The receptors (in Figure 1 left) of the membrane form the sensoric inputs of the cell (the “antennae” with which signals from the environment can be taken up). The active proteins (in Figure 1 right) are the motoric outputs of the cell. The coupling of a “stimulated” receptor with an active protein triggers a metabolic pathway or a behavioral reaction in the cell. The signals from the environment specify the collection of input-output-complexes. Each complex connects incoming signals (stimuli) with appropriate behavioral reactions. Consequently, the cellular behavior is controlled by stimuli from the environment and not by the genes that are in the cell.
The molecular structure of the cell membrane reveals a liquid-crystalline semiconductor with gates (receptors) and tunnels (effectors). The plasmalemma is from its molecular structure, as well as from its mode of action, directly comparable with a computer chip and as such the plasmalemma also functions like an information processor. In this computer-similar scheme the membrane and the proteins embedded in it, i.e. their IMP-receptors and -effectors, function as structural basis of the chip.
The individual IMP complexes are the equivalent of the hard drive and the corresponding genes serve as a programmed store. Each individual receptor, and thus each integral membrane protein, is calibrated to only receive one kind of signal from the environment and to respond to it. The entire population of receptors on the surface of the cell membrane functions as a physical filter by which the cell “explores” its environment. Different cell types are an expression of different populations of IMP.
When an egg is fertilized by a sperm cell, the zygote begins to divide into a number of embryonic cells. The embryonic cells differentiate into special cell types (e.g. bone-, muscle-, blood-, nerve cells and others). The way the cells differentiate they create unique populations of tissue specific integral membrane proteins. The bigger part of IMP receptors defines the cell specific function and the developmental line.
Figure 2
The behavior or the physiological character of a cell is determined by their population of receptors that process thousands of signals from the environment. Consequently, cellular function and health status are directly connected with the variety of IMP receptors and the spectrum of environmental signals to which they are oriented. Most cells of the human body have a low population of character determining receptors that are also called self receptors. The individuality of each human is partly determined by the unique combination of IMP self receptors which only he himself possesses. Combinations of self receptors are comparable with the fingerprints with which one can unambiguously identify each individual. To illustrate the mode of action of the cell membrane we have displayed in 2 figures the uptake and transfer of signals from the environment.
Figure 3
Reaction of an IMP to a chemical signal
As soon as the receptor answers with a corresponding signal, the protein portions change as well. The rearranged shape of the activated receptor is now able to link up with a specific effector.
The antenna of the receptor receives from and sends to both IMP types signals, actually physical ones and energetic ones (thus chemical ones as well as electromagnetic ones). The reaction to corresponding chemical signals is not different here from the reaction to electromagnetic signals (see Figure 4).
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Figure 4
The activated receptor (in Figure 5) has, due to its good fitting shape, established a connection to the effector  via an active link. By the coupling, the effector by itself is activated and begins to have an effect.Â
Embedded in the lipid double layer are the receptor protein (gate) and the effector protein (tunnel).
Figure 5
Effector proteins control the condition, the movement, the metabolic processes and the protective mechanism of the cells. The effectors serve for regulating genetic activities as well. In Figure 5, the effector is displayed as a “tunnel”. In the activated state, this tunnel enables pulsating positively charged ions to penetrate the cell and thus to change the energetic state of the cell.
For the cell, the change of its energy state is an electrical signal that for example can activate or inhibit specific genetic programs. The cells recognize the environment by converting energies of the electromagnetic spectrum to biologically useful information. Different receptor proteins convert light, sound, x-rays, radio waves, microwaves, and extremely low frequencies (ELF) to cell connections by activating effector proteins which on the other hand can provoke a depolarization of the membrane, an activation of the enzyme system of the cytoplasm or a regulation of genetic processes.
This way, the energetic field controls behavior and condition of cells and tissues. Compared with the regulation of cell activities by chemical influences, the energetic regulation has the primacy.
Quantum physics and cell biology
In the seventies, quantum physicists completely changed our view of the universe. The dualism not only penetrated into Newton’s vision of matter and energy, the quantum physicists also recognized that the universe is solely composed of energy, and matter is nothing else but concentrated or bundled energy. Modern physics demonstrated that the invisible energy potentials which had been ignored by biologists for a long time, exert an extremely lasting influence on the shape and the working of matter.
The bio-physicists discovered that it is completely unscientific to play down the significance of invisible energetic forces in the development of the behavior and the health of living beings.
The conventional belief of biochemistry is based on the theory that information between the cells of a living being can only be transmitted by chemicals. Contrary to that, the biophysicists claim that power fields are not only able to transport information but, past that, can transmit biological information by two orders of magnitude more efficiently and finally faster than conventional chemical signals.
(Mc Clare, Resonance in Bioenergetics, Annals NY Acad, Sci., 227/74, 1974)
Thus it is conclusively accepted that large distances - connections from cell to cell and also from organism to organism - can be overcome by transmission and reception of electromagnetic signals by means of membrane receptors. Electromagnetic power fields have, provably, a big influence on every kind of biological regulation. Specific frequencies and patterns of electromagnetic fields have an effect on cell division, gene regulation, DNA-, ribonucleic acid (RNA)- and protein synthesis, protein adaptation and -activity, morphogenesis, regeneration as well as nerve conductor function and nerve growth. Energy from power fields can be absorbed by resonant proteins.
Such energies provoke reshaping changes in the protein structure and this mechanical change of structure enables the protein to perform chemical “work”. (T. Y. Tsong, Deciphering the Language of Cells, TIBS, 14/XX, 1989). The electromagnetic forces in the environment can be “sensed” by specific IMP receptors. The resulting changes in the protein structure, provoked by activated receptors, convert the received signal to cell activities.
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Genopuls Theory