This article presents the theoretical and experimental foundations for Wave Translation, a concept that expands the Central Dogma of molecular biology by demonstrating that genetic information can be transmitted and expressed through physical fields. The authors, P.P. Gariaev, M.J. Friedman, and E.A. Leonova-Gariaeva, argue that the genome functions as a Quantum Biocomputer, utilizing principles of linguistics, holography, and quantum physics to manage the complex development and maintenance of an organism.

Theoretical Foundations of Wave Genetics

The conventional model of genetics, while foundational, is insufficient to explain the rapid, long-range communication required for morphogenesis. The theory of the Linguistic-Wave Genome is built on several key principles to address this gap:

• Holographic & Linguistic Genome: The genome is not merely a chemical blueprint but also a holographic and textual information system. The chromosome apparatus acts as a dynamic hologram, containing the non-local blueprint for the organism's four-dimensional structure. This information is linguistic in nature, with DNA sequences forming complex "texts" that are read and understood by the cell's machinery in context, not just as simple triplets.
• Quantum Non-Locality: The genome is proposed to be a quantum system that leverages entanglement (the Einstein-Podolsky-Rosen effect) for instantaneous communication. This allows the organism's billions of cells to function as a single, super-coherent entity, instantly sharing information about their metabolic and genetic states.
• Soliton Wave Transmission: Information is read from the DNA "text" and transmitted along the molecule via solitons—stable, non-dispersing acoustic and electromagnetic waves. These solitons act as carriers of genetic information, translating the nucleotide sequence into a dynamic wave signal.

Experimental Verification: The Pancreas Regeneration Model

The article provides powerful experimental evidence for wave translation through a series of studies on rats with alloxan-induced type 1 diabetes, a condition that destroys the pancreas.

• Methodology: Using a specially designed laser, researchers were able to capture the wave-based genetic and morphogenetic information from the pancreas and spleen tissue of healthy newborn rats. This information, encoded in a modulated broadband electromagnetic field, was then transmitted to the diabetic rats.
• Results: The diabetic rats that received the wave information showed a complete normalization of their blood sugar levels and survived, whereas 95% of the control group perished. Histological analysis confirmed that the treated rats had undergone a full regeneration of their pancreatic tissue, with the formation of new, healthy islets of Langerhans.
• Significance: This groundbreaking result was achieved without any physical transplantation. Remarkably, the healing effect was successfully transmitted over distances ranging from several centimeters to 20 kilometers, confirming the non-local, wave-based nature of the genetic information. The experiment demonstrates that wave information can program the organism's endogenous stem cells to perform complex organ regeneration.

Conclusion and Implications

The concept of wave translation fundamentally changes our understanding of genetics. It establishes that genetic information is dualistic, existing as both a material substance (the DNA molecule) and as an energetic field. The successful regeneration of a complex organ using only its corresponding wave information opens the door to a new era of regenerative and informational medicine. This technology holds the potential for developing non-invasive therapies for a wide range of diseases, including cancer and genetic disorders, by correcting the foundational wave blueprints that guide the health and structure of the organism.

References

1. Gariaev, P.P., & Tertyshny, G.G. (1999, January 6). Priority Patent Application N 99/01/L. Federal Institute of Industrial Property, PCT Receiving Office, Starfield, LTD.
2. Mazur, A.I., & Grachev, V.N. (1985). Electrochemical Indicators. Moscow: Radio and Communication.
3. Prangishvili, I.V., Gariaev, P.P., Tertyshny, G.G., Maximenko, V.V., Mologin, A.V., Leonova, E.A., & Muldashev, E.R. (2000). Spectroscopy of radio wave radiation from localized photons: A path to quantum non-local bio-informational processes. Sensors and Systems, 9(18), 2-13.
4. Gariaev, P.P., Prangishvili, I.V., Tertyshny, G.G., Mologin, A.V., Leonova, E.A., & Muldashev, E.R. (2000). Genetic structures as a source and receiver of holographic information. Sensors and Systems, (2), 2-8.
5. Gariaev, P.P., Tertyshny, G.G., & Tovmash, A.V. (2007). Experimental in vitro studies on the holographic display and transfer of DNA in a complex with its surrounding information. New Medical Technologies, (9), 42-53.
6. Gariaev, P.P. (2009). Linguistic-Wave Genome: Theory and Practice. Kiev. 220 p..
7. Gariaev, P.P., Kokaya, A.A., Mukhina, I.V., Leonova-Gariaeva, E.A., & Kokaya, N.G. (2007). Effect of modulated biostructures electromagnetic radiation on the course of alloxan-induced diabetes in rats. Bulletin of Experimental Biology and Medicine, (2), 155-158.
8. Gariaev, P.P., Kokaya, A.A., Leonova-Gariaeva, E.A., Muldashev, E.R., Mukhina, I.V., Smelov, M.V., Tertyshny, G.G., Tovmash, A.V., & Yaguzhinsky, L.S. (2007). Theoretical models of wave genetics and the reproduction of wave immunity in experiments. New Medical Technologies / New Medical Equipment, (1).
9. Gariaev, P.P., Birshtein, B.I., Iarochenko, A.M., Marcer, P.J., Tertyshny, G.G., Leonova, K.A., & Kaempf, U. (2001). The DNA-wave biocomputer. CASYS - International Journal of Computing Anticipatory Systems, 10, 290-310.
10. Jiang, Kanzhen. (1981). The method to change an organism’s heredity and the device to transmit biological information. Soviet Union Patent No. 1828665.
11. Popp, F.A. (2000). In L. Beloussov, F.A. Popp, V. Voeikov, & R. van Wijk (Eds.), Biophotonics and Coherent Systems. Proceedings of the 2nd A. Gurwitsch Conference. Moscow State University Press.
12. Shcherbak, V.I. (2003). Arithmetic inside the universal genetic code. BioSystems, 70, 187–209.
13. Lagerkvist, U. (1978). «Two out of Three»: an alternative method for codon reading. Proceedings of the National Academy of Sciences, USA, 75, 1759-1762.
14. Gariaev, P.P. (1997). Wave Genetic Code. Monograph. Moscow, 108 p.
15. Tertyshny, G.G., & Gariaev, P.P. (2007). Wave genetic nanotechnologies for biosystem control: Theory and experiments. New Medical Technologies, (7), 49-64.
16. Gariaev, P.P., Chudin, V.I., Komissarov, G.G., Berezin, A.A., & Vasiliev, A.A. (1991). Holographic Associative Memory of Biological Systems. Proceedings of SPIE, The International Society for Optical Engineering: Optical Memory and Neural Networks, 1621, 280-291.
17. Allison, S.A., Sorlie, S.S., & Pecora, R. (1990). Brownian Dynamics Simulations of Wormlike chains: Dynamics Light Scattering from 2311 Base Pair DNA Fragments. Macromolecules, 23, 1110-1118.
18. Gariaev, P.P., Tertyshny, G.G., & Tovmash, A.V. (2007). Experimental in vitro studies on the holographic display and transfer of DNA in a complex with its surrounding information. New Medical Technologies, (9), 42-53. (Note: This is a duplicate of reference #5).
19. Burlakov, A.B., Burlakova, O.V., & Golichenkov, V.A. (1999). Distant interactions between loach embryos of different ages. Doklady Akademii Nauk, 368(4), 562-564.
20. Budagovsky, A.V., Turovtseva, N.I., & Budagovsky, I.V. (2001). Coherent electromagnetic fields in remote intercellular interaction. Biophysics, 46(5), 894-900.
21. Gariaev, P.P., et al. (2011, December 16). Method and device for registration of radio wave spectra of objects. Patent Application PCT/RU2011/000790..
22. Gariaev, P.P., et al. (2011, October 10). Method for controlling the metabolism of biosystems and a system for its implementation. Patent Application PCT/RU2011/000790.
23. Korneev, A.A. Holographic interpretation of the nanostructural phenomenon of Don Eigler.
24. Kukushkin, A.K. Methods of biophysical research: Optical properties of molecules.
25. Laser Diagnostics in Biology and Medicine: Laser Quasi-Elastic Light Scattering Spectroscopy.
26. Denisyuk, Y.N. On the reflective properties of running waves of intensity in the recording of dynamic volume holograms..
27. "Quadratic" Medium. Great Encyclopedia of Oil and Gas.
28. Mazurenko, Y.T. Holography of time, spectral holography and spectral nonlinear optics.
29. Staselko, D.I. Yuri Nikolaevich Denisyuk - the founder of three-dimensional optical holography. How it was. To the fiftieth anniversary of the discovery of a physical phenomenon.
30. Y.N. Denisyuk and three-dimensional optical holography.
31. Gariaev, P.P., et al. (2014). Method of producing PCR product of DNA Using Wave Replicas of DNA (Genes) and the Device for its Implementation. Patent Application 2014/06578.
32. Gariaev, P.P., et al. (2014). Materialization of DNA Fragment in Water through Modulated Electromagnetic Irradiation: Preliminary Report. DNA Decipher Journal, 4(1), 01-02.
33. Montagnier, L., et al. (2012). Remote transmission of electromagnetic signals including nanostructures amplifiable into a specific DNA sequence. Patent Application WO 2012/142565 A2.
34. Denisyuk, Y.N. (1974). Journal of Technical Physics, 44, 131. (Note: Original source was incomplete).
35. Denisyuk, Y.N. (1981). Letters to the Journal of Technical Physics, 7, 641. (Note: Original source was incomplete).
36. Denisyuk, Y.N., Andreoni, A., Bondani, M., & Potenza, M.A.C. (2000). Optics Letters, 25, 890.
37. Staselko, D.I., Denisyuk, Y.N., & Sizov, V.N. (2002). Optics and Spectroscopy, 93, 500.
38. Gariaev, P.P. Linguistic-Wave Genetics (LWG).
39. Gariaev, P.P. Bioinformational Technologies: Regeneration of Lost Organs.
40. Korneev, A.A. The Hoop Phenomenon #5: Mental Holography.
41. Bohm, D. (1957). Causality and Chance in Modern Physics. (Note: The source cites the 1959 Russian translation).
42. Berkovich, S. (2001). On the “barcode” functionality of the DNA, or The phenomenon of Life in the physical Universe.

Download an original document (PDF)