Ultraweak photon emission and the role of DNA: experiments and interpretations
József Bódis1,2,3, József Berke1,4, István Gulyás1, Ilya V. Volodyaev5; 1National Laboratory on Human Reproduction, University of Pécs, Pécs, Hungary; 2HUN-REN–PTE Human Reproduction Scientific Research Group, Pécs, Hungary; 3Department of Obstetrics and Gynecology, Medical Scholl, University of Pecs, Pécs, Hungary; 4Dennis Gabor University, Department of Drone Technology and Image Processing, Budapest, Hungary; 5Moscow State University, Moscow. Russia
Abstract
In cells, the primary sources of biophoton emissions are oxidative processes that produce photons during molecular relaxation through reactive oxygen species. Photon emissions occur primarily in mitochondria, cell membranes and peroxisomes, with specific patterns associated with metabolic activity and stress response. Measurement of biophoton emissions requires very sensitive detection methods, such as photomultiplier tube or CCD cameras. In addition to these classic recognised data, there are a number of observations and hypotheses that are likely to broaden our view of these areas. First of all, coherent biophoton theory claims that biophoton emission allows quantum-based information transfer, photons can serve as internal communication signs in the cells. Despite the many objections to this, some aspects of this area may well prove valuable to our field, as we will discuss in more detail. Second, gradually growing evidence shows that cells can communicate through light emissions, including serious works by respected authors. While light emissions are generally appreciated to indicate physiological conditions, they are also suggested to trigger responces in adjacent cells. Third, the latest results suggest that DNA can emit photons under certain circumstances. The importance of this observation lies in the fact that the DNA may serve not only as an information carrier, but also as a participant in chains of light-based processes. All of these will be analysed in our talk, with particular attention to the evidence and refutations and potential implications of such ideas.
The exploration of the functional significance and mechanisms of biophoton emissions remains of paramount importance. The study of coherent biohpoton fields and potential light-based cell communication deepens the understanding of information processing in biological systems. The role of ultra-weak photon emissions, especially related to DNA, is an emerging area that can have a serious impact on understanding cell communication. Further research on strict and precisely planned experiments is essential for the complex exploration of the phenomenon and its potential applications.
Speaker
József Bódis
National Laboratory on Human Reproduction, University of Pécs, Pécs; HUN-REN–PTE Human Reproduction Scientific Research Group, Pécs; Department of Obstetrics and Gynecology, Medical Scholl, University of Pecs, Pécs
Hungary
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