Therapeutic use of fields and frequencies
Living organisms and electromagnetic fields
Many of the pulsed magnetic fields used in bio-electromagnetic devices are only briefly on-rhythm. But this short period is long enough to create movement in the body. The movement of electromagnetic radiation in the body leads to ion transfer, increased blood and lymph flow. Electromagnetic waves can be used for diagnostic and therapeutic purposes because the functioning of all living organisms is based on energy. Most of the studies have mistakenly considered the body as only a mechanical and biochemical entity. Every cell in the body is a transmitter and receiver of electromagnetic information.
Below are some examples of how humans, animals and plants produce and react to electromagnetic fields:
During migration butterflies, grasshoppers and even blind birds find their way perfectly. Salamanders and turtles also use magnetic fields for navigation. We now know that magnetite* is found in the tissues and brains of insects, birds, reptiles and amphibians.
Many species of fish can follow each other in organized patterns due to the magnetic fields created by the magnetite in their bodies. Whiskers of dogs, cats and other animals are known as antennas due to their sensitivity to electromagnetic fields. In plants, the sharp tips of leaves, pine needles and blades of some grasses act as electricity antennas!
Fish, dolphins and whales use the Earth’s magnetic fields and sonar for navigation and communication. The behavior of some animals has long been used to predict earthquakes. Birds chirp at the wrong time of day, mother cats move their kittens, snakes seek shelter.
Steve Haltiwanger, in his paper “The Electrical Properties of Cancer Cells”, explains how the body functions in part as a living electrical circuit:
Body cells are made of matter. Matter itself is made up of atoms, which are a mixture of negatively charged electrons, positively charged protons, and neutral neutrons. In electrical equipment, the carriers of electrical charge are electrons. In the body, electricity is carried by a number of mobile charge carriers as well as electrons.”
Although many authorities argue that electricity in the body is carried only by charged ions, Robert O. Becker et al have shown that electron semi-conduction also occurs in biological polymers.
The main charge carriers in living organisms are negatively charged electrons, positively charged hydrogen protons, positively charged sodium, potassium, calcium and magnesium ions and negatively charged anions, especially phosphate ions. The work of Mae Wan Ho and Fritz Popp shows that cells and tissues are also guided and communicated by photons and electromagnetic radiation.
The body uses the outer cell membrane and positively charged inorganic ions held in varying concentrations on each side of the cell membrane to create a cell membrane potential (a voltage difference across the membrane) and a strong electric field around the cell membrane. This electric field provides the necessary energy source for a significant number of cellular activities, including membrane transport, and the generation of electrical impulses in the brain, nerves, heart, and muscles. Storing electric charge in the membrane and creating an electric field creates a function similar to a battery.
As a result of liquid crystal semiconductors, cytoskeletal proteins can somehow connect to this field and energize cellular structures such as genetic material. The voltage potential across the membrane creates an amazing and powerful electric field.
The body uses the mitochondrial membrane and positively charged hydrogen ions to create a strong membrane potential across the mitochondrial membrane. By using the function of the electron transport chain, hydrogen ions are kept in a high concentration outside of the mitochondrial membrane. This concentration difference creates a membrane potential of about 4,000,000 V/m in the mitochondria. The flow of electricity, which is of the proton type, across the inner mitochondrial membrane is used to power a molecular motor called ATP synthase, which transfers negatively charged phosphate anions to ADP, thereby producing ATP.
ADP, ATP, and other phosphate-carrying molecules are electrochemical molecules that exchange phosphate charges between other cellular molecules. The body uses phosphate electricity by charge transfer to activate and deactivate body enzymes, which causes these enzymes to assume different structural states and switch between active and inactive states. Thus enzymes and other proteins such as cytoskeletal proteins may act as electrical switches.
Electronic function of the extracellular matrix
According to James Oshman, the communication systems of living organisms take place through chemical and energy languages. Chemical communication in the body is mainly done through the circulatory system. According to Western medical models, energy communication in the body is almost exclusively done in the nervous system.
This system communicates through a chain of liquid crystals of polymeric proteins. It is through this chain that information is carried in biological systems through endogenous DC electric fields, their associated magnetic fields, and very weak photon emission.
This chain of liquid crystal connections allows electrons and photons to move in and out of cells. In my view, cytoskeletal filaments act as electronic semiconductors and fiber optic cables that integrate the flow of information both within the cell and with other cells. This chain enables the organism to function as a biological hologram.
Electromagnetic field therapy
Cells have the ability to respond positively to a low electromagnetic stimulus if certain criteria are met.
• The stimulus must be in the correct region of the electromagnetic spectrum.
• It must have an exact frequency or a specific frequency combination.
• It must have the correct volume
• Must have correct waveform
• It should be prescribed in the form of correct amounts
• And it should target exactly the desired location
In bioelectromagnetic medicine, the response of living cells to beneficial electromagnetic radiation is known as “inductive coupling”. As soon as the electromagnetic fields inside the cell are exposed to electromagnetic radiation, they start to move. Along with this active process, the relevant biochemical responses are also activated. Inductive coupling is used in a large number of effective bioelectrical medical devices.
Bioelectromedical therapy may use many parts of the electromagnetic spectrum: electric current, magnetism, electromagnetism, visible light, far infrared (FIR), ultraviolet (UV) radiation, and heat (in the form of certain IR wavelengths). Frequency treatments can increase cellular energy, normalize membrane conductance, reduce oxidative stress, reduce levels of inflammatory chemicals in the blood, and boost immune function.
Book title: Bioresonance the Truth
Author: loannis Anagnostopoulos
Translator: Dr. Mehtab Jahan Shahtalab
References
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