The term "biophoton" comes from the words "bio" - biological and "photon" - light energy, an elementary particle from the group of bosons, which is a carrier of electromagnetic interactions.

 

Biophotons mean biological light, or the emission of ultra-low light that is used by all biological organisms to support life. Biophotons are a natural form of electromagnetic radiation generated by biochemical processes occurring in organisms.

The first discoveries regarding biophotons took place in the first half of the 20th century. At first they were treated as heresy in science, but now an increasing number of scientists are beginning to notice that biophotons are emitted from all cells and are used by our body to direct, organize and connect all biological processes. They can be called the silent language of DNA.

 

Alexander Gurwitsch (1874-1954), a Russian biologist, was the first to discover ultra-weak light emission produced by living organisms. He is the creator of the theory of morphogenetic fields. Based on the results of his experiments, he postulated the existence of a regulating "biofield". Georges Lakhovsky (1870—1942), however, noticed a similar phenomenon and summarized his concepts in three points:

 

1. Life arises from radiation.

2. It is controlled by radiation.

3. Disturbance of the vibrational balance causes the destruction of life.

 

Of all the scientists conducting research in the field of biophotonics, the most famous is the German biophysicist Fritz-Albert Popp, who used the term "biophoton" to distinguish it from "bioluminescence". According to Popp, light is constantly absorbed, released and produced by DNA molecules in the nucleus of every cell of all living organisms. These biophotons create a dynamic, coherent network of light. As he himself claimed:

 

“There is light in our cells. Every living matter, every organic cell - human, plant or animal - radiates extremely faint light; weak, but coherent, i.e. orderly. This light, which, like laser rays, is excellent for transmitting signals, probably regulates all energy fields in the body and intra- and intercellular communication. 1

 

After Popp's discoveries, many more biophoton researchers appeared. For example. in 1981, V. P. Kaznacheyev, director of the Institute of Clinical and Experimental Medicine in Novosibirsk, and L. P. Mikhailova, head of the physics department at the same institute, after many years of research, wrote a book: "Ultraweak radiation as intercellular interaction", where they called the electromagnetic intercellular interaction "electromagnetic bio-information".

 

Among the most famous scientists researching biophotons we have:

 

F.A. Popp, H.P. Diirr, M. Bischof, R. H. Dicke, M. Galie, R. Neurohr, G. Altmann, J.J. Chang, H. Frohlich, Q. Gu, Kih Li, B. Ruth, B. Kohler, K. Lambing, R. Neurohr, G. Becker, H.L. Konig, W. Peschka, Ewald Fisher, W. Nagi, H. Inaba, J. Slawinski, G. Cilento, R. Van Wijk, B. Chuirot, J. Fisch, R.P. Bajpai, L.V. Belousov, S. Cohen, H.H. Jung, K. Sup-Soh, M. Lipkind, V.L Voiekol, Y. Aoshima, Z. Michiniewicz, J. Swain, Yu. Yan, D. Schlesinger, A. Dolf, Y. Yan, A. Chotia, G.N. Lewis, Y. Oashima, L. Van Klitzing, Marco Bischof, G.J. Hyland, S. Suzuki, M. Kobayasi, M. Hiramatsu, E. Ciccolo, J. Benviste, L. Wolfgang, T.V. Veselova, V.A. Veselovskii, A.B. Rubin, RZ. Bochrarovi wielu innych.

All cells in our body have receptors on their cell membrane that are able to read different frequencies of energy contained in the electromagnetic spectrum. This spectrum includes ultraviolet, infrared and visible light.

 

Soft (low-level) lasers produce visible and infrared light. Different frequencies of light actually transmit information to cells, information that is understood by receptors on the cell membrane and on the membrane of the cell's mitochondria (the cell's enzyme engine).

 

Biophotons are very similar to laser light in that they are emitted by our cells as coherent, monochromatic, directional and highly organized light energy (they work similarly to laser lights).

 

According to Popp's research, in cellular tissue light is transported almost without loss through single cells over long distances. He believed that this tissue was quite "transparent" to ultra-weak cellular radiation. In Popp's experiments, when the injured part of the cucumber seedling was covered, a strong spontaneous increase in photon emission could be observed in other places, located far from the damaged place. 2

 

However, the experiments of D. F. Mandoli and W. R. Briggs led them to conclude that coherent light travels surprisingly long distances in plant tissue, of the order of several centimeters. 3

 

Three Soviet researchers: V.P. Kaznacheyev, S.P. Shurin, L.P. Mikhailov demonstrated in over 5,000 experiments that living cells transmit biological information using photons (namely ultraviolet radiation), also from a certain distance. They placed cells in a nutrient solution in two quartz glass vessels with walls touching each other. They infected one of the cell cultures with a virus. It turned out that disease symptoms occurred almost simultaneously in the cells of the neighboring colony. A similar thing happened when cells absorbed lethal doses of ultraviolet radiation or were poisoned by sublimate. In each case, they manifested identical cases of disease, including those cells that were separated from infected cells by quartz glass. However, in these samples there was no trace of the chemicals and viruses that were placed in neighboring cells. Only when normal glass was used instead of quartz glass did the cell disease not spread to the neighboring colony. 4

Scientific experiments suggest that we not only "consume" light through the products of photosynthesis, but that we are beings made of light. F. A. Popp additionally noticed that cells have the ability to absorb light. They absorb photons (and the information contained in them) supplied by external light, e.g. sunlight. They store this light and pass it on. But cells also have their own biophotonic light, which they emit. In the apparatus he and his assistants constructed for observing biophotons in cells, Popp first observed how they first released the light they had accumulated, and only after waiting from several minutes to several hours was he able to observe the constant ultra-weak light emitted by the examined cells.

 

It follows that, depending on our experiences during the day, we may feel that we are losing or gaining energy. When we are exhausted, we can waste our precious photonic energy. The detection and characterization of human biophoton emission has led to the suggestion that it has potential future applications in medicine. It was noted that the emission of biophotons will vary depending on the functional state of the organism. If a disease such as cancer affects certain cells, they will emit a different photonic signature than healthy cells of the same type. For example, cancer cells and healthy cells of the same type can be distinguished based on typical differences in biophoton emission. In this way, biophotons can contain information about the body's health and can be used to diagnose and monitor various diseases.

 

The theory behind biophoton therapy is based on the work of Dr. Franz Morell and has been expanded to include the work of doctors L.C. Vincent and F.A. Poppa. They believed that light could influence electromagnetic oscillations, or body waves, and regulate enzyme activity. Scientists found that photons emitted from biological systems make it possible to observe life processes without damaging the body, analyze them from various points of view, and provide a comprehensive understanding of the phenomenon of life. 5

Both Popp and his team in Germany, as well as D. H. J. Schamhart at the Department of Molecular Cell Biology at the University of Utrecht (the Netherlands), as well as a group of scientists gathered around the physicist Franco Musumeci at the University of Catania in Italy, noticed that cancer cells, as they grow numbers and depending on their malignancy, they radiate light more and more strongly - even without prior exposure, while healthy cells, unlike diseased ones, glow less brightly. However, it is good to remember that high intensity of light is not a sign that the cell is harmful. This is confirmed by Popp's measurements of biophoton radiation. Normal cells, when they divide, that is, even when they behave individually (meaning they are independent), show higher light radiation than cancer cells. 6

 

The cause of cancer by specific molecules is widely considered to be the result of unfavorable metabolism. The biochemist H. A. Fischer (Paul Ehrlich Institute in Frankfurt am Main) showed that nerve cells transmit stimuli across the synaptic gap not only by means of transmitter substances (e.g. acetylcholine), but, more likely, mainly by biophotons. 7 The work of F. A. Popp's research group cooperating with the Pharmaceutical Institute of the University of Kiel has yielded results indicating that antispasmodic agents, i.e. substances that block the conduction of stimuli, can specifically extinguish photon exchange in the synaptic cleft through repeated excitation (so-called "multi-resonance"). 8

 

Popp claimed that as long as we have communication in the body, there will be no cancer. According to him, cancer is a communication disorder between cells whose growth is precisely programmed. And coherence, i.e. the ability to transmit information using electromagnetic waves, is the basic language of communication between light waves from the physical point of view. Cancer, according to this view, is a disruption of coherence that occurs in communication through light. Popp proved his claim with research. In experiments, it turned out that cancer cells - after exceeding a certain threshold - completely destroy the coherence of light. When there is no coherence, the cell is unable to communicate with others. Instead of improving, communication deteriorates even more when a new cell is taken in, and then cancer develops. 9

 

As density increases, healthy cells form an actual "tissue" that is physically and chemically different from the corresponding disorganized groups of cells. Cancer cells lose this collective property as they become more malignant. As a result, they remain independent individuals, grow uncontrollably and grow into healthy tissue. Popp said about cancer cells: "Their disease is the loss of the ability to interfere, that is, the loss of coherence, which makes them deaf to the signals of their own species, and eventually to their own as well. Thus, these disturbed individuals believe that they are alone in the world.” 10

 

Please remember that "coherent" does not mean "orderly". Coherence does not mean that we have ordered laser beams that go out in only one direction. Orderly means the ability to interact, meaning that each part can communicate with another part. Popp explained this in his book "Biology of Light" using the metaphor of an orchestra: "During a concert, it is not only about each musician using his instrument correctly. This is taken for granted. The way and moment of playing a specific tone on each instrument, the mutual tuning of the playing of individual musicians, their harmony and cooperation - all this determines the artistic level of the concert. 11

 

In healthy cells, the ability to coordinate and the stability of wave phases, i.e. their coherence, is important. This singularity has nothing to do with wavelength. Cells cancel each other's wave fields in order to communicate.

For example, after conducting experiments, Popp noticed that when groups of cells were irradiated with ultraviolet light of 380 nanometers or longer, the DNA was destroyed to such an extent that only two or three percent of it remained undamaged. After exposing these cells to light again, but this time at a reduced intensity, the previously induced damage was removed within a day. Popp claimed that such repair under the influence of light is possible in all living organisms. 12

 

Our bodies are not only chemical, but also electromagnetic. And if you increase the electromagnetic energy field (also known as "chi" or "prana") by increasing the proper activity of biophotons, you can encourage the body to heal itself.

 

It is therefore easy to understand that the more we increase the potential of biophotons, primarily in terms of broadly understood quality, the more health and radiant life there will be - in plants, animals and the human species. Light is energy and energy is information, so when cells are able to receive better information, they perform better.

Popp said: “The photons released in the body during digestion from the chemical compounds of food actually come from the sun. They were originally stored by plants. They trigger various housekeeping functions in the body. Appetite stimulates and synthesizes enzymes important in the digestive process, which indirectly and subjectively determine the quality of food. Once again clearly and clearly: photons are released in the digestive process at the right time and in the right place, activating necessary life functions and deactivating unnecessary chemical reactions.” 15

 

The quality of food can only be understood through the prism of its effect on our body's radiation field. High quality means that food intake improves order in the body, low quality leads to "dissonance". This is the TRANSMISSION OF FOOD according to F.A.'s theory. Poppa. 16

 

This basic process also gives meaning to evolution: "life" means preventing sunlight from dissipating into low-value thermal energy. Living beings block the spontaneous dissipation of high-value solar energy through the highest power ability to collect it and transform it into information. Consequently, the ability to accumulate light should be considered an important basis for food quality. 17

 

Food, according to Popp, is the stimulator of evolution. Accumulation capacity is a key function that depends on the wavelength, species and, of course, the biological time of a living thing, which includes age, condition and rhythm. From this perspective, living things are complex sets of antennas capable of receiving and transmitting over a wide spectrum. High frequencies (short waves) primarily regulate regulatory processes at the molecular and cellular level, while low frequencies control "social" communication within and between individuals.

 

In this way, sunlight does not "thermalize" but is rather divided into smaller and smaller portions of energy. Popp compared it to throwing stones into still water, creating circular waves of varying lengths and amplitudes that propagate through time and space, dissipating away from the point of impact. In this case, the sun serves as a source that rhythmically throws photons into the "sea of ​​Earth's evolution." Living things are waves and at the same time they feed on waves. 18

14 Fritz-Albert Popp, Przekaz jedzenia, przeł. Anna Sztajer, Virgo, Warszawa 2010, s. 100

15 Fritz-Albert Popp, Przekaz jedzenia, przeł. Anna Sztajer, Virgo, Warszawa 2010, s. 187

16 Fritz-Albert Popp, Przekaz jedzenia, przeł. Anna Sztajer, Virgo, Warszawa 2010, s. XLII

17 Fritz-Albert Popp, Przekaz jedzenia, przeł. Anna Sztajer, Virgo, Warszawa 2010, s. 152

18 Fritz-Albert Popp, Przekaz jedzenia, przeł. Anna Sztajer, Virgo, Warszawa 2010, s. 61-62

19 https://biophotonlight.com/biophoton-research/

20 Pratap Raychaudhuri,  Double helical structure of DNA molecule and photon. Speculations in Science and Technology, 4(3): s. 267–270

21 https://oisf.org/understanding-the-higgs-1-frozen-light-2/

22 Fritz-Albert Popp, Biologia światła, przeł. Jerzy Kuryłowicz, Widza Powszechna, Warszawa 1992, s. 151-152

23 https://www.studocu.com/en-us/document/harvard-university/introduction-to-systematic-reviews-and-meta-analysis-methods/1-dietrich-klinghardt/33374619

24 Fritz-Albert Popp, Przekaz jedzenia, przeł. Anna Sztajer, Virgo, Warszawa 2010, s. XXX