Water Catholyte with Device Kangen and Gergana Genova, Career TV

Partners:
Gergana Genova, electrolyzers Kangen for waters catholyte and anolyte
http://www.kangen-water.bg

Catholyte - Ionized with Electrolysis Water as Prophylaxis of Molecular and Cellular Level and giving Health and Energy

Prof. Ignat Ignatov

The report examines the properties of the electrochemically activated waters catholyte and anolyte with Electrolyzer device. It is accepted that the acid-alkaline nature of water in the human body has a pH of 7.0. When the pH is above 7.0, the water is alkaline. When the pH is less than 7.0, the water is acidic.

The water Catholyte has using with electrolysis and has the following characteristics:

  1. Alkalyne with pH > 9
  2. Negative oxidation redox potential (ОRP)
  3. Presence of Hydrogen– H2

The water Anolyte has the following characteristics:

  1. Acidic pH < 5
  2. Positive oxidation redox potential (ОRP)
  3. Presence of oxygen – O2

The main indicators of drinking water for influence on human health are alkaline-acidic values ​​(pH values) and oxidation-reduction potential (ORP). The optimal vital functions in the healthy organism depends of the water with parameters in the norm of these indicators. There are some of these indicators in a healthy man: arterial blood is with pH 7.37-7.45, venous - pH 7.32-7.42, pancreas-secreted secretion is effective only with pH 8,3 and that of the liver and bile with pH 7.1. Changes in blood pH below 7.3 and over 7.5 have serious problems in the body's condition. When diluting the water, its pH and ORP values ​​change logarithmically, not linearly, i.e., values ​​minus 500 mV are not 5 times, and 10 to 50 times higher than minus 100 mV. To ensure its vital processes, the body regulates precisely the optimal pH and ORP values of its systems, using its own energy for this purpose. When food and fluids that the body intakes have the same or close to its optimal pH and ORP values, it is not overburdened with a large expenditure of energy required aligning them to its requisite limits. Otherwise, a significant amount of energy is spent, resulting in general loss of vitality and weakening of the immune system. As a result, some chronic diseases enter an acute phase and/or preconditions are created for the emergence of new ones.

The factors for health and longevity have been under research for years. They are quality water and food, heredity, body weight, physical activity, mental status, diseases. The human body in adults consists of 50-55% water. In studies there is clear evidence that people who drink quality mountain water live longer (Prof. Ignatov et al, 2012). In research, the other factors are similar and the distance between the settlements in the mountains and the field is 50-70 km. Studies were conducted on water from the mountains of Bulgaria, Germany, Switzerland, Chile. The aim is to look for the secret of longevity. Quality water provides additional years of life.
http://www.medicalbiophysics.bg/en/project.html
This is due to its alkalinity, chemical composition and structure. A mathematical model of water for health and longevity has been created (Prof. Ignatov, Ass. Prof. Oleg Mosin, 2013). The model is based on spectral analysis of water (Prof. Antonov, Prof. Ignatov, 1998). The spectrum is the "language" of water molecules. They are associated with electromagnetic hydrogen bonds between oxygen from one and hydrogen from another water molecule. The molecules form clusters with energy. Figure 1 shows hydrogen bonds between water molecules. In Fig 1a we have a chaotic arrangement of water molecules, as in water. In Fig. 1b we have the structure of water molecules, as in the electrochemically activated water catholyte. Catholyte is alkaline and anolyte is acidic water. The first is applied more for alkalizing the body and the second for disinfection.

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Fig. 1а. Chaotic arrangement of hydrogen bonds between water molecules


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Fig. 1b. Arrangement of high-energy hydrogen bonds between water molecules

The larger the energy of hydrogen bonds between water molecules, the healthier the person. Tumor cells tear the highest energy bonds in water. Evidence was provided by Prof. Antonov in 1990 with white mice. At 8,95 μm are the highest energy bonds in water. A spectral analysis was carried out of blood serum of people between 50 and 70 years of age. The control group was of people in good health and the research group was of people with tumour diseases (Prof. Ignatov, 2012). With a microscope it can be seen how life struggles to keep the hydrogen bonds in people with tumour diseases. A reasonable question arises – what to do in terms of prevention and how to structure new high-energy hydrogen bonds, which can inhibit the growth of tumour cells at a molecular level? Mountain and glacier waters create high-energy hydrogen bonds in the human body. In tap water the maximum of oscillation in hydrogen bonds at 8,95 μm is up to 25 units. Analyses show that in mountain water it is (40-50), while in glacier water it is 60-70 units. In Catholyte water it is 90 units. This is unique and gives a chance to many people to quickly recover and improve their biophysical status. The American scientific journal with high impact factor “Advances in Physics Theories and Applications” has published an article on the biophysical properties of Catholyte water (Prof. Ignatov, Ass. Prof. Mosin, Kirov, 2016). It is a well-known scientific fact that tumor cells develop in acidic conditions, and in an alkaline medium they are suppressed. The electrochemically activated Catholyte water, which is alkaline, is accepted well by man. It reduces the symptoms of fatigue, gastrointestinal problems; the body is balanced at a molecular level. One of the secrets of Catholyte water is its antioxidant action. A theoretical model indicates the presence of electrons in alkaline Catholyte water for antioxidant activity (prof. Ignatov et al, 2017), and indirect antioxidant activity of zinc ions and manganese ions (Prof. Ignatov, Ass. Prof. Mosin, 2015) The method for color corona spectral analysis (Prof. Ignatov, 2007) shows the bioelectrical status of the person. The method is also applicable in the study of different types of water.
http://www.medicalbiophysics.bg/en/kirlian_effect.html
Figure 2 shows corona photographs of water (Fig. 2a) and Catholyte water (Fig. 2b). The difference in the electric corona emission is impressive. It is due to the larger permittivity of Catholyte water. This is determined by the arrangement of water molecules in clusters with the highest energy bonds in water.

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Corona emission of tap water
(Prof. Ignatov)


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Corona emission of
Catholyte water (Prof. Ignatov)


Water with pH 8.5 is suitable for everyday use. Water with higher pH is consumed in smaller quantities.

Contacts: team of Prof. Ignatov: mbioph@abv.bg; mbioph@gmail.com

Publications:

  1. Ignatov, I., Karadzhov, S., Atanasov, A., Ivanova, E., Mosin, O. V. (2014) Electrochemical Aqueous Sodium Chloride Solution (Anolyte and Catholyte) as Types of Water. Mathematical Models. Study of Effects of Anolyte on the Virus of Classical Swine Fever Virus, Journal of Health, Medicine and Nursing, Vol. 8, pp.1-28. (PDF file)
    http://www.iiste.org/Journals/index.php/JHMN/article/view/18734
  2. Karadzov, S., Atanasov, A., Ivanova, E., Mosin, O. V., Ignatov, I. (2014) Mathematical Models of Electrochemical Aqueous Sodium Chloride Solutions (Anolyte and Catolyte) as Types of Water. Study of the Effects of Anolyte on the Virus of Classical Swine Fever Virus, Journal of Health, Medicine and Nursing, Vol. 5, pp. 30-55.
  3. Gluhchev, G., Ignatov, I., Karadzhov, S., Miloshev, G., Ivanov, N., Mosin, O.V. (2015) Electrochemically Activated Water. Biophysical and Biological Effects of Anolyte and Catholyte as Types of Water, Journal of Medicine, Physiology and Biophysics, Vol. 10, pp. 1-17. (PDF file)
    http://www.iiste.org/Journals/index.php/JMPB/article/view/19687
  4. Ignatov, I., Gluhchev, G., Karadzhov, S., Miloshev, G., Ivanov, N., Mosin, O.V. (2015) Preparation of Electrochemically Activated Water Solutions (Catholyte/Anolyte) and Studying Their Physical-Chemical Properties, Journal of Medicine, Physiology and Biophysics, Vol. 11, pp. 1-21. (PDF file)
    http://www.iiste.org/Journals/index.php/JMPB/article/view/20405
  5. Gluhchev, G., Ignatov, I., Karadzhov, S., Miloshev, G., Ivanov, N., Mosin, O.V. (2015) Biocidal Effects of Electrochemically Activated Water, Journal of Health, Medicine and Nursing, Vol. 11, pp. 67-83. (PDF file)
    http://www.iiste.org/Journals/index.php/JHMN/article/view/20412
  6. Gluhchev, G., Ignatov, I., Karadzhov, S., Miloshev, G., Ivanov, N., Mosin, O. V. (2015) Studying of Virucidal and Biocidal Effects of Electrochemically Activated Anolyte and Catholyte Types of Water on Classical Swine Fever Virus (CSF) and Bacterium E. coli DH5, Journal of Medicine, Physiology and Biophysics, Vol. 13, pp. 1-17. (PDF file)
    http://www.iiste.org/Journals/index.php/JMPB/article/view/22414
  7. Ignatov, I., Gluhchev, G., Karadzhov, S., Miloshev, G., Ivanov, N., Mosin, O. V. (2015) Preparation of Electrochemically Activated Water Solutions (Catholyte/Anolyte) and Studying of their Physical-Chemical Properties, Journal of Medicine, Physiology and Biophysics, Vol. 13, pp. 18-38. (PDF file)
    http://www.iiste.org/Journals/index.php/JMPB/article/view/22415
  8. Ignatov, I., Gluhchev, G., Karadzhov, S., Miloshev, G., Ivanov, N., Mosin, O. V. (2015) Preparation of Electrochemically Activated Water Solutions (Catholyte/Anolyte) and Studying of their Physical-Chemical Properties, Journal of Health, Medicine and Nursing, Vol. 13, pp. 64-78. (PDF file)
    http://www.iiste.org/Journals/index.php/JHMN/article/view/22411
  9. Ignatov, I., Mosin, O. V. , Gluhchev, G., Karadzhov, S., Miloshev, G., Ivanov, N., (2015) Studying Electrochemically Activated NaCl Solutions of Anolyte and Catholyte by Methods of Non-Equilibrium Energy Spectrum (NES) and Differential Non-Equilibrium Energy Spectrum (DNES), Journal of Medicine, Physiology and Biophysics, Vol. 14, pp. 6-18. (PDF file)
    http://www.iiste.org/Journals/index.php/JMPB/article/view/22973
  10. Ignatov, I, Gluhchev, G., Karadzhov, S., Ivanov, N., Mosin, O.V. (2015) Preparation of Electrochemically Activated Water Solutions (Catholyte/Anolyte) and Studying Their Physical-Chemical Properties, Journal of Medicine, Physiology and Biophysics, Vol. 16, pp. 1-14. (PDF file)
    http://www.iiste.org/Journals/index.php/JMPB/article/view/24706
  11. Gluhchev, G., Ignatov, I., Karadzhov, S., Miloshev, G., Ivanov, N., Mosin, O.V. (2015) Electrochemically Activited Water: Biophysical and Biological Effects of Anolyte and Catholyte Types of Water, European Journal of Molecular Biotechnology, Vol. 7., No. 1, pp. 12-26. (PDF file)
  12. Ignatov, I., Mosin, O.V., Gluhchev, G., Karadzhov, S., Miloshev, G., Ivanov, N. (2015) The Evaluation of Mathematical Model of Interaction of Electrochemically Activated Water Solutions (Anolyte and Catholyte) with Water, European Reviews of Chemical Research, Vol. 2., No. 4, pp. 72-86. (PDF file)
  13. Gluhchev, G., Ignatov, I., Karadzhov, S., Miloshev, G., Ivanov, N., Mosin, O.V.(2015) Studying the Antimicrobial and Antiviral Effects of Electrochemically Activated NaCl Solutions of Anolyte and Catholyte on a Strain of E. Coli DH5 and Classical Swine Fever (CSF) Virus, European Journal of Medicine, Vol. 9., No. 3., pp. 124-138. (PDF file)
  14. Ignatov, I., Mosin, O.V., Gluhchev, G., Karadzhov, S., Miloshev, G., Ivanov, N.(2016) Studying Electrochemically Activated NaCl Solutions of Anolyte and Catholyte by Methods of Non-Equilibrium Energy Spectrum (NES) and Differential Non-Equilibrium Energy Spectrum (DNES), Journal of Medicine, Physiology and Biophysics, Vol. 20, pp. 13-23. (PDF file)
    http://www.iiste.org/Journals/index.php/JMPB/article/view/28211
  15. Ignatov, I., Mosin, O.V., Kirov, P. (2016) Matematical Model of Kangen Water® Biophysical and Biochemical Effects of Catholyte, Advances in Physics Theories and Applications, Vol. 51, pp. 33-55.(PDF file)
    http://iiste.org/Journals/index.php/APTA/article/view/28008
  16. Mehandjiev, D., Ignatov, I., Karadzhov, I., Gluhchev, G., Atanasov, A. (2017) On the Mechanism of Water Electrolysis, Journal of Medicine, Physiology and Biophysics, Vol. 31, pp. 23-26. (PDF file)
    http://www.iiste.org/Journals/index.php/JMPB/article/view/36666
  17. Mehandjiev, D., Ignatov, I., Karadzhov, S., Gluhchev, G., Atanasov, A. (2017) Processes in Catholyte and Anolyte as Result of Water Electrolysis, European Journal of Molecular Biotechnology, 5, No. 1, pp. 23-29.(PDF file)
  18. Gluhchev, G., Ignatov, I., Karadzhov, S., Miloshev, G., Ivanov, N., Mosin, O.V. (2016) Antimicrobial and Solutions Antiviral Effects of Electrolytic Water Solutions of Sodium Chloride (Anolyte/Catholyte) on a Strain of E. Coli DH5 and the Classical Swine Fever Virus (CSF), Problems of Biological, Medical and Pharmaceutical Chemistry, No. 1, pp. 21-31. (PDF file)
    https://bmpcjournal.ru/en/bmfc-2016-03-04
  19. Gluhchev, G., Mehandjiev, D., Ignatov, I., Karadzhov, S., Pesheva, Y., Atanasov, A. (2018) Water Electrolysis - Processes in Catholyte and Anolyte Results with Differential Non-equilibrium Water Spectrum, European Journal of Medicine, Vol. 6, No. 1, pp. 3-12. (PDF file)
  20. Ignatov, I., Karadzhov, S., Gluhchev, G., Yakimov, I. (2018) Electromagnetically Activated Water - Properties and Effects, Bulgarian Journal of Public Health, Vol. 10, No.4, 63-69.
  21. Vassileva, P., Voykova, D., Ignatov, I., Karadzhov, S., Gluhchev, S., Ivanov, N., Mehandjiev, D. (2019) Results from the Research of Water Catholyte with Nascent (Atomic) Hydrogen, Journal of Medicine, Physiology and Biophysics, Vol.52, pp. 7-11 (PDF file)
    https://www.iiste.org/Journals/index.php/JMPB/article/view/46543
  22. Yakimov, I., Ignatov, I. (2019) Hydration and Properties of Water in Football for Excellent Shape, Int. Conference on Medicine and Football, Sofia, Bulgaria, Journal of Medicine and Sport, pp. 46-51.
  23. Ignatov, I., Gluhchev, G. (2019) Effects of Electrochemically Activated Water Catholyte and Anolyte on Human Health, 8th World Congress on Immunology, Pulsus, London, Vol. 3, pp. 12-13. (PDF file)
    https://www.pulsus.com/conference-abstracts-files/nursing-immunology-2019-keynote.digital/files/assets/common/downloads/nursing-immunology-2019-keynote.pdf
  24. Toshkova, R., Ignatov, I., Zvetkova, E., Gluhchev, G. (2019) Effects of Catholyte Water on the Development of Experimental Graffi Tumor on Hamsters, Cells&Cellular Life Sciences Journal, Vol. 4, No.1, 000140 (PDF file)
    https://medwinpublishers.com/CCLSJ/CCLSJ16000140.pdf
  25. Toshkova, R., Ignatov, I., Zvetkova, E., Gluhchev, G. (2019) Effects of Catholyte Water on the Development of Experimental Graffi Tumor on Hamsters, European Journal of Medicine, Vol. 7 No 1, pp. 45-56. (PDF file)
  26. Gluhchev, G., Ivanov, N., Ignatov, I., Karadzhov, S., Miloshev, G., Mosin, O. V. (2015) Virucidal and Bactericidal Effects of Electrochemically Anolyte and Catholyte Types of Water on Classical Swine Fever Virus and Bacterium E. Coli DH5, Water: Hygiene and Ecology, No. 1-2 (3): 3-10. (PDF file)
    https://iiste.org/Journals/index.php/JMPB/article/view/22414
  27. Atanasov, A., Karadzhov, S., Ivanova, E., Mosin, O. V., Ignatov, I. (2014) Study of the Effects of Electrochemical Aqueous Sodium Chloride Solution (Anolyte) on the Virus of Classical Swine Fever Virus. Mathematical Models of Anolyte and Catolyte as Types of Water, Journal of Medicine, Physiology and Biophysics, Vol.4, pp. 1-26 (PDF file)
    https://www.iiste.org/Journals/index.php/JMPB/article/view/15016
  28. Popova, T. P., T. Petrova, Karadzhov, S. (2016) Investigation of the Biocidal Effect of Electrochemically Activated Aqueous Sodium Chloride Solution on Gram-negative Pathogenic Bacteria. Int. J. Curr. Microbiol. App. Sci., Vol. 5 No.1, pp. 624-632. (PDF file)
    https://www.ijcmas.com/abstractview.php?ID=63&vol=5-1-2016&SNo=63
  29. Popova, T., Petrova, T., Karadzhov, S. (2016) Investigation of the Action of the Anolyte after Different Storage Times on the Gram-negative Bacteria, Int. J. Curr. Microbiol. App. Sci., Vol. 5, No. 9, pp. 530-539. (PDF file)
    https://www.ijcmas.com/abstractview.php?ID=915&vol=5-9-2016&SNo=59
  30. Popova, T., Petrova, T., Karadzhov, S., Krustanova. G. (2016) Investigation of the Biocidal Effect of Electrochemically Activated Aqueous Sodium Chloride Solution on Staphylococcus aureus. Traditions and Modernity in Veterinary Medicine, Scientific Journal of the Faculty of Veterinary Medicine of University of Forestry, Sofia, Vol. 1, No.1, pp. 67-72. (PDF file)
    https://scij-tmvm.com/vol./vol.1/T.Popova%20et%20al..pdf
  31. Popova, T., Petrova, T., Kaleva, M., Karadzhov, S. (2018) Comparative Study of the Effect of Electrochemically Activated Water Solutions on Pseudomonas aeruginosa, Acta Microbiologica Bulgarica, Vol. 34, No.3, 160-164. (PDF file)
    https://actamicrobio.bg/archive/september-2018/amb-september-2018-article-4.pdf
  32. Ignatov, I., Mehandjiev, D., Vassileva, P., Voykova, D., Karadzhov, S., Gluhchev, G., Ivanov, N. (2019) Research of Water Catholyte of Presence of Nascent (Atomic) Hydrogen (H*). Hydrogen and Nascent Hydrogen of the Reactions for Origin of Life in Hot Mineral Water, European Journal of Medicine, Vol. 7, No. 2, pp. 99-105. (PDF file)
    http://ejournal5.com/journals_n/1579189002.pdf
  33. Popova, T., Petrova, T.. (2018) Antibacterial Activity of Electrochemically Activated Water Solutions on Pseudomonas aeruginosa After Four Weeks Storage, Int. J. Curr. Microbiol. App. Sci., Vol. 7, No.10, pp. 3379-3386. (PDF file)
    https://www.ijcmas.com/abstractview.php?ID=10504&vol=7-10-2018&SNo=391
  34. Petrova, T., T. Popova, T. (2018) Electrochemically Activated Aqueous Solutions – Essence, Action and Some Aspects of Application. Traditions and modernity in veterinary medicine, Scientific Journal of the Faculty of Veterinary Medicine of University of Forestry, Sofia, Vol. 3, No.2 (5), pp. 34-42. (PDF file)
    https://scij-tmvm.com/vol./vol.3/2/34-42.pdf
  35. Popova, T., Petrova. T. (2018) Disinfection of Leafy Vegetables with Activated Waters, Journal of Advances in Agriculture, Vol. 9, pp. 1534-1545.
  36. Popova, T., Petrova, T., Petrichev, M., Valyova, M. (2019) Action of Activated Waters on Plants After Adverse Chemical Effects, Imitating Acid Rain. Bulgarian Journal of Agriculture Science, Vol. 25, No.4, 638–645. (PDF file)
    https://www.agrojournal.org/25/04-04.html
  37. Popova, T. (2019) Disinfection of Fruits with Activated Water, Journal of Advances in Agriculture, Vol. 10, pp. 1864-1872. https://rajpub.com/index.php/jaa/article/view/8462
  38. Popova, T. (2019) Examination of Effect of Electrochemically Activated Water Solutions on Candida albicans after Different Periods of Storage (2019) Journal of Advances in Agriculture, Vol. 10, pp. 1886-1894. (PDF file)
    https://rajpub.com/index.php/jaa/article/view/8473
  39. Gluhchev, G., Ivanov, N. (2014) Electrochemically Activated Water, J. of Ecological Engineering and Environment Protection, Vol. 2, pp. 68-73
  40. Toshkova, R., Zvetkova, E., Ignatov, I., Gluhchev, G. (2019) Effects of Catholyte Water on the Development of Experimental Graffi Tumor on Hamsters, Bulgarian Journal of Human Health, Vol. 11, No. 3, pp. 60-73. (PDF file)
    http://ncphp.government.bg/files/spisanie/3-2019_BG_Journal.pdf
  41. Ignatov, I., Gluhchev, G, (2019) Effects of Electrochemically Activated Water Catholyte and Anolyte on Human Health, 8th World Congress on Immunology, Pulsus, London, Vol. 3, pp. 12-13.(PDF file)
    https://www.pulsus.com/conference-abstracts-files/nursing-immunology-2019-keynote.digital/files/assets/common/downloads/nursing-immunology-2019-keynote.pdf
  42. Ignatov, I., Toshkova, R., Zvetkova, E., Gluhchev, G. (2019) Research of Catholyte Water on Experimental Graffi Tumor on Hamsters. Kangen Device for Catholyte Water, Cancer Stem Cell, Epidemiology and Surgery, Seoul. pp. 25
  43. Ignatov, I., Toshkova, R., Zvetkova, E., Gluhchev, G. (2019) Research of Catholyte Water on Experimental Graffi Tumor on Hamsters. Kangen Device for Catholyte Water, Journal of Medicine, Physilogy and Biophysics, Journal of Medicine, Physilogy and Biophysics, Vol. 59, pp. 1-9. (PDF file)
    https://www.iiste.org/Journals/index.php/JMPB/article/view/49571
  44. Ignatov, I. (2019) Electrochemically Activated Water Catholyte for Activation of Shape and Recovery in the Sport, Int. Conference on Medicine and Football, Sofia, Bulgaria, Journal of Medicine and Sport, No. 3-4, pp. 112-119
  45. Antonov, A., Galabova,T.(2016), Water Known and Misterious, Sofia, ISBN: 978-954-2987-23-9
  46. Nikolova, M., Gluhchev, G., Karadzhov,S., Hristova, I., Ivanov, N. (2016), Investigation on the Changes in pH, Redox Potential, Free Chlorous and Antimicrobial Activity of Ionized Water (Anolite) at Dfferent Storage Conditions, Ecological Engineering and Environment Protection, No.4, pp. 22-26
  47. Dimitrova, L., Kussovski, V., Tsvetkova, I., Mihaylova,S., Ivanov,N., Gluhchev, G., Najdenski, H. (2015)Bactericidal Effect of Electrochemically Activated Water on the Aerobic Bacterial Population of Digestate, Ecological Engineering and Environment Protection, No. 4, pp. 23-32 http://ecoleng.org/Contents4.2015.html#3
  48. Ivanov, N. (2000), Investigation on the Mechanism of the Structure Influence of some Physical and Physical-Chemical Factors on the Water Structure in Cotton Seeds, (PhD Thesis)
  49. Ignatov, I., Gluhchev, G., Karadzhov, G., Yaneva, I., Valcheva, N., Dinkov, G,, Popova, T., Petrova, T., Mehandjiev, D., Akszjonovich, I. (2020) Dynamic Nano Clusters of Water on Waters Catholyte and Anolyte: Electrolysis with Nano Membranes, Physical Science International Journal. Vol. 24, No.1, pp. 46-54. (PDF file) 
    http://journalpsij.com/index.php/PSIJ/article/view/30173
  50. Karadzhov, S., Ignatov, I., Najdenski, H., Popova, T., Luepcke, W., Gluhchev, G., Kolev, N., Balabanov, S. (2019) Distribution Trends of African Swine Fever Virus (ASFV) through Water, European Journal of Molecular Biotechnology, Vol. 7, No. 2, pp. 123-125. (PDF file)
  51. Ignatov, I., Gencheva, N., Marinov, T., Yaneva, I., Angelcheva, M., Dinkov, G., Angushev, I. (2020) Electrochemically Activated Water Catholyte for the Activation of Hydrogen Ions and ATP for Sport’s Shape and Recovery, Journal of Advances in Medicine and Medical Research, 32 (4): 112-119. (PDF file)
    http://www.journaljammr.com/index.php/JAMMR/article/view/30407
  52. Popova, T., Petrova, T., Ignatov, I., Karadzhov, S. (2020) Preliminary In Vitro Investigations on The Inhibitory Activity of The Original Dietary Supplement Oxidal® On Pathogenic Bacterial Strains, Journal of Advances in Agriculture, 11: 37-43. (PDF file)
    https://rajpub.com/index.php/jaa/article/view/8693
  53. Ignatov, I. (2020) Antiviral Effects of Nano Colloidal Silver, Water Catholyte, Oxidal with Methylene Blue. Possible Effects of Influence over Coronavirus SARS-CoV and SARS-2 CoV-2 with Disease COVID-19, Global Congress on Infectious Diseases, SciTech Infectious Diseases 2020. (PDF file)
    https://www.scitcentralconferences.com/speakers/global-congress-on-infectious-diseases-hivaids?fbclid=IwAR2cSp78pgAenfNSDvNL3aVwNTG7XOGObZS4SoPZzpkf_HAi4E8HlHF6AT0
  54. Ignatov, I. (2020) Antibacterial and Antiviral Effects of Water Catholyte, Oxidal with Methylene Blue and Colloidal Silver, Journal of Medicine, Physiology and Biophysics, Vol. 65, pp. 26-31. (PDF file)
    https://www.iiste.org/Journals/index.php/JMPB/article/view/52294
  55. Popova, T., Petrova, T., Ignatov, I., Karadzhov, S., Dinkov, G., (2020) Antibacterial Activity of the Original Dietary Supplement Oxidal® in Vitro, Journal of Advances in Agriculture; 11: 71-78. (PDF file)
    https://https://rajpub.com/index.php/jaa/article/view/8716
  56. Ignatov, I. (2020) Antiviral Effects of Water Catholyte, Oxidal with Methylene Blue and Colloidal Silver. Possible Mechanism of Influence over Coronavirus SARSr-CoV and SARSr-CoV-2 with Disease COVID-19, Journal of Health, Medicine and Nursing, Vol. 73, pp. 96-101 (PDF file)
    https://www.iiste.org/Journals/index.php/JHMN/article/view/52483
  57. Ignatov, I. (2020) Antiviral Effects of Water Catholyte, Oxidal with Methylene Blue and Colloidal Silver. Possible Mechanism of Influence over Coronavirus SARSr-CoV and SARSr-CoV-2 with Disease COVID-19, Journal of Infectious Diseases and Research, Vol. 3, issue S1. (PDF file)
    https://www.scitcentral.com/articles.php?journal=62&type=2&articleStat=Current%20Issues
  58. Mehandjiev, D., Gluhchev, G., Ignatov, I., Vassileva, P., Voykova, D., Ivanov, N. (2020) Electrochemically Activated Water – Anolyte. Nascent Oxygen,  International Research Journal of Pure and Applied Chemistry,  Vol. 21, No. 9, pp. 78-82. (PDF file)
    https://journalirjpac.com/index.php/IRJPAC/article/view/30200 
  59. Karadzhov, S., Ivanova, E., Ignatov, I., Atanasov, A. (2021) Efffects of Anolyte Water on the Classical Swine Fever Virus: Effects of Oxidants and pH, Uttar Pradesh Journal
    of Zoology, Vol. 42, No10, pp. 90-97.  (PDF file)
    https://mbimph.com/index.php/UPJOZ/article/view/2141
  60. Ignatov. I., Angelcheva, M., Angushev, I. (2021) Doses of Са 2+ , Mg 2+ , K + , Nа + , Mn 2+  and Zn 2+  in Mountain Spring and Mineral Waters in Hydration Reaction During Sport Training and Recovery; Combination with Vitamins,  Journal of Pharmaceutical Research International, Vol. 33, No. 16, pp. 76-85.  (PDF file)  
    https://www.journaljpri.com/index.php/JPRI/article/view/31299
  61. Ignatov, I., Gluhchev, G., Neshev, N., Mehandjiev, D. (2021) Structuring of Water Clusters Depending on the Energy of Hydrogen Bonds in Electrochemically Activated Waters Anolyte and Catholyte, Bulgarian Chemical Communications, Vol. 53, No. 2, pp. 234-239.  (PDF file)
    http://www.bcc.bas.bg/BCC_Volumes/Volume_53_Number_2_2021/bcc-53-2-2021.pdf
  62. Mehandjiev, D., Ignatov, I., Neshev, N., Gluhchev, G., Drossinakis, Ch. (2022) Hydrogen Bond Energies in Formation of Water Molecules Clusters, Physical Science International Journal. (PDF file)
    https://journalirjpac.com/index.php/IRJPAC/article/view/30200
  63. Vassileva, P., Voykova, D., Gluhchev, G., Ignatov, I., Mehandjiev, D. (2022) Nascent Oxygen – Active Component, Obtained by Means of Electrochemical Activation of Water, Journal of Chemical Technology and Metallurgy, Vol. 57, No 3, pp. 545-549.
    https://dl.uctm.edu/journal/node/j2022-3/13_22-04_br_3_pp_545-549.pdf

List of scientific publications, where Prof. Ignat Ignatov is cited
Topic: Electrochemically activated waters – Anolyte and Catholyte

UK
Gajda, I., Obata, O., Greenman, J., Jeropoulis, I. (2020) Electroosmotically generated disinfectant from urine as a by-product of electricity in microbial fuel cell for the inactivation of pathogenic species, Scientific Reports, Nature, Vol. 10, No. 5533 https://www.nature.com/articles/s41598-020-60626-x

Cited:
Gluhchev, G, Ignatov, I., Karadzhov, S., Miloshev, G., Ivanov, N., Mosin, O.V. (2015) Electrochemically Activited Water: Biophysical and Biological Effects of Anolyte and Catholyte Types of Water, European Journal of Molecular Biotechnology, Vol. 7 No. 1, pp. 12-26.

Zhou, Y., Endelberg, D.L. (2018) Application of a Modified Bi-polar Electrochemistry Approach to Determine Pitting Corrosion Characteristics, Electrochemistry Communications, 93, 158-161. https://www.sciencedirect.com/science/article/pii/S1388248118301553

Zhou, Y., Endelberg, D.L. (2020) On the Application of Bipolar Electrochemistry to Characterise the Localised Corrosion Behaviour of Type 420 Ferritic Stainless Steel, Metals, 10(6), 794 https://www.mdpi.com/2075-4701/10/6/794

Zhou, Y., Stevens, N., Endelberg, D.L. (2021) Corrosion Electrochemistry with a Segmented Array Bipolar Electrod, Electrochemica Acta, Vol. 375, 137668.
https://www.sciencedirect.com/science/article/pii/S0013468620320612#

Zhou, Y., Endelberg, D.L. (2021) Time-lapse Observation of Pitting Corrosion in Ferritic Stainless Steel Under Bipolar Electrochemistry Control, Journal of
Electroanalytical Chemistry, Vol. 899, 115599.
https://www.sciencedirect.com/science/article/abs/pii/S1572665721006251

Cited:
Ignatov, I., Mosin, O. V. , Gluhchev, G., Karadzhov, S., Miloshev, G., Ivanov, N., (2015) Studying Electrochemically Activated NaCl Solutions of Anolyte and Catholyte by Methods of Non-Equilibrium Energy Spectrum (NES) and Differential Non-Equilibrium Energy Spectrum (DNES), Journal of Medicine, Physiology and Biophysics, Vol. 14, pp. 6-18.

Clayton, G. E., Thorn, R. M. S., Reynolds, D. M. (2021) The efficacy of chlorine-based disinfectants against planktonic and biofilm bacteria for decentralised point-of-use drinking water, Clean Water, Nature, 4, 48.
https://www.nature.com/articles/s41545-021-00139-w

Cited:
Ignatov. I., Mosin, O.V., Gluhchev, G., Karadzhov, S., Miloshev, G., Ivanov, N. (2015) The evaluation of the mathematical model of interaction of electrochemically
Activated water solutions (anolyte and catholyte) with water. European Reviews of Chemical Research, 4(2):72–86.

SOUTH KOREA
Cha, Chun-Nam et al. (2016) Virucidal efficacy of a fumigant containing orth-phenylphenol against classical swine fever virus and porcine reproductive and respiratory syndrome virus, Korean Journal of Veterinary Service, 39 (2): 117-124. http://www.koreascience.or.kr/article/JAKO201621650894229.page

Cited:
Gluhchev, G., Ignatov, I., Karadzhov, S., Miloshev, G., Ivanov, N., Mosin O. V. (2015) Studying the virucidal and biocidal effects of electrochemically activited anolyte and catholyte types of water on classical swine fever virus (CSF) and bactrerium E. coli DH5. J Med Physiol Biophysics, 13: 1-18.

Park, D. H. et al. (2021) Nano-dry-salt deposition on electret nonwoven confers anticoronaviral effect while retaining aerosol filtration performance, Environmental Science: Nano, 10.
https://pubs.rsc.org/en/content/articlelanding/2021/en/d1en00369k/unauth

Cited:
Gluhchev, G., Ignatov, I., Karadzhov, S., Miloshev, G., Ivanov, N., Mosin, O.V. (2015) Studying the Antimicrobial and Antiviral Effects of Electrochemically Activated NaCl Solutions of Anolyte and Catholyte on a Strain of E. Coli DH5 and Classical Swine Fever (CSF) Virus, European Journal of Medicine, 9 (3), 124-138.

INDIA
Lata, S. et al. (2016) Anti bacterial Effectiveness of Electro- Chemically Activated (ECA) Water as a Root Canal Irrigant- An In-vitro Comparative Study, Journal of Clinical and Diagnostic Research, 10 (10): 138-142. https://jcdr.net/article_fulltext.asp?issn=0973- 709x&year=2016&volume=10&issue=10&page=ZC138&issn=0973-709x&id=8699

Cited:
Ignatov I, Mosin, O.V., Gluhchev G, Karadzhov S, Miloshev G, Ivanov N. The evaluation of the mathematical model of interaction of electrochemically activated water solutions (anolyte and catholyte) with water. European Reviews of Chemical Research. 2015;4(2):72–86.

Dube, K., Jain, P., (2018) Electrolyzed Saline…an Alternative to Sodium Hypochlorite for Root Canal Irrigation, Clujul Med, 91(3): 322–327 https://medpharmareports.com/index.php/mpr/article/view/863

Cited:
Ignatov. I., Mosin, O.V., Gluhchev, G., Karadzhov, S., Miloshev, G., Ivanov, N. The evaluation of the mathematical model of interaction of electrochemically activated water solutions (anolyte and catholyte) with water. European Reviews of Chemical Research. 2015;4(2):72–86.

Mukherejee, S. et al. (2020) Biomedical application, drug delivery and metabolic pathway of antiviral nanotherapeutics for combating viral pandemic: A review, Environmental Research, 191. https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7443328/

Cited:
Ignatov, I. (2020) Antiviral Effects of Water Catholyte, Oxidal with Methylene Blue and Colloidal Silver. Possible Mechanism of Influence over Coronavirus SARSr-CoV and SARSr-CoV-2 with Disease COVID-19, Global Congress of Infectious Diseases, USA. 

RUSSIA
Bachir, V. M., Pogorelov, A.G. (2018) Universal Electrochemical Technology for Environmental Protection, International Journal of Pharmaceutical Research & Allied Sciences, 7(1):41-57 https://ijpras.com/storage/models/article/M4pNNzDuXHM26gZuwHIaEUypJjCmNZ62tlhBY HXEzsxdeZAejBj27E233YHn/universal-electrochemical-technology-for-environmental- protection.pdf

Cited:
Georgi Gluhchev, Ignat Ignatov, Stoil Karadzhov, Georgi Miloshev, Nikolay Ivanov, Oleg Mosin. (2015) Electrochemically Activited Water: Biophysical and Biological Effects of Anolyte and Catholyte Types of Water. European Journal of Molecular Biotechnology, 7, 1, pp. 12-26.

Gluhchev, G., Ignatov, I., Karadzhov, S., Miloshev, G., Ivanov, N., Mosin, O.V. (2015) Electrochemically Activated Water. Biophysical and Biological Effects of Anolyte and Catholyte as Types of Water, Journal of Medicine, Physiology and Biophysics, 10, 1-17. Ostrik, A. A, et al. (2020) Small RNAs of Mycobacterium tuberculosis in Adaptation to Host-Like Stress Conditions in vitro, Applied Biochemistry and Microbiology, 56, 381-386.
https://link.springer.com/article/10.1134/S0003683820040122

Cited:
Ignatov I, Gluhchev G, Karadzhov S, Miloshev G, Ivanov N, Mosin O.V. (2015a) Preparation of electrochemically activated water solutions (catholyte/anolyte) and
studying their physical- chemical properties. J Health Med Nurs 13:64–78. Ipatova, L. G.; Марченко, С. Д.; Потупчик, Т. В. (2021) Possibilities of application of disinfectant Anolit ANK SUPER in medical organizations, Vrach, 32 (5), 67-74

Cited:
Ignatov, I., Gluhchev, G., Karadzhov, S., Miloshev, G., Ivanov, N., Mosin, O. V. (2015) Preparation of Electrochemically Activated Water Solutions (Catholyte/Anolyte) and Studying of their Physical-Chemical Properties, Journal of Medicine, Physiology and Biophysics, Vol. 13, pp. 18-38.

VIETNAM
Truong Nhu Ngoc Vo et al. (2018) Efficacy of Electrochemically Activated Water Solution in Gingivitis Treatment, Journal of Pharmaceutical Investigation, 49, 323-329. https://link.springer.com/article/10.1007/s40005-018-00419-7

Cited:
Ignatov I, Gluhchev G, Karadzhov S, Miloshev G, Ivanov N, Mosin O.V. (2015a) Preparation of electrochemically activated water solutions (catholyte/anolyte) and studying their physical- chemical properties. J Health Med Nurs 13:64–78.

Ignatov I, Gluhchev G, Karadzhov S, Miloshev G, Ivanov N, Mosin O. V. (2015b) Preparation of electrochemically activated water solutions (catholyte/anolyte) and studying their physical-chemical properties. J Med Physiol Biophys 11:1–21

NGUYỄN THỊ THANH HẢI (2018) NGHIÊN CỨU CẢI TIẾN QUY TRÌNH ĐIỀU CHẾ DUNG DỊCH SIÊU OXY HÓA VÀ ỨNG DỤNG TRONG KHỬ TRÙNG NƢỚC THẢI BỆNH VIỆN, 1-161. http://gust.edu.vn/media/26/uftai-ve-tai-day26123.pdf

Cited:
Ignatov I, Gluhchev G, Karadzhov S, Miloshev G, Ivanov N, Mosin O (2015) Preparation of electrochemically activated water solutions (catholyte/anolyte) and studying their physical- chemical properties. J Med Physiol Biophys 11:1–21

Thị Lâm, Đan C., Đỗ, L. T., Mai, X. T., &amp; Đỗ Thị, K. S. (2021). Đánh giá tác dụng điều trị của dung dịch điện hoá Suporan tại vết thương bỏng. Tạp Chí Y học Thảm Hoạ Và Bỏng, (5), 38-52. https://jbdmp.vn/index.php/yhthvb/article/view/73

Cited:
Ignatov, I., Gluhchev, G., Karadzhov, S., Miloshev, G., Ivanov, N., Mosin, O. V. (2015) Preparation of Electrochemically Activated Water Solutions (Catholyte/Anolyte) and Studying of their Physical-Chemical Properties, Journal of Medicine, Physiology and Biophysics, Vol. 13, pp. 18-38.

COLOMBIA
Ariza Aguilar, J.F. (2020) Sistema descentralizado de desalinización de agua basado en energía solar para generar volúmenes de agua segura en comunidades indígenas de La Guajira,Univecidad Nacional de Colombia, Departamento de Ingeneria Civil y Agricola, 381. https://repositorio.unal.edu.co/handle/unal/78574

Cited:
Gluhchev, G., Ignatov, I., Karadzhov, S., Miloshev, G., Ivanov, N., Mosin, O.V. (2015) Biocidal Effects of Electrochemically Activated Water, Journal of Health, Medicine and Nursing, Vol., 67-83.

USA
Ramsey, C. l. (2021) Comparison of Plant Trait Biometrics for Paired Invasive and Non-Invasive Species to Magnetized Seed and Watering Treatments, Global Journal of Agricultural Innovation, Research &amp; Development, 32-48.

Cited:
Ignatov, I., Mosin, O.V., Kirov, P. (2016) Matematical Model of Kangen Water® Biophysical and Biochemical Effects of Catholyte, Advances in Physics Theories and Applications, Vol. 51, pp. 33-55.

LITHUANIA, SPAIN
Riesute, R., Salomskiene, J., Moreno, D. S., Gustiene, S. (2021) Effect of yeasts on food quality and safety and possibilities of their inhibition, Trends in Food Sciences&amp;Technology, 108, 1-10.
https://www.sciencedirect.com/science/article/abs/pii/S0924224420306968#

Cited:
Gluhchev, G, Ignatov, I., Karadzhov, S., Miloshev, G., Ivanov, N., Mosin, O.V. (2015) Electrochemically Activited Water: Biophysical and Biological Effects of Anolyte and Catholyte Types of Water, European Journal of Molecular Biotechnology, 7 (1), 12-26.

CANADA
Cayemitte, P. E. (2021) Électro-activation de solutions aqueuses de lactate et ascorbate de calcium et étude de leurs effets antibactériens sur les cellules végétatives et spores de Bacillus cereus ATCC 14579, Philosophiæ doctor – Université Laval.
https://www.bac-lac.gc.ca/eng/services/theses/Pages/item.aspx?idNumber=1273433675

Cited:
Gluhchev, G, Ignatov, I., Karadzhov, S., Miloshev, G., Ivanov, N., Mosin, O.V. (2015) Electrochemically Activited Water: Biophysical and Biological Effects of Anolyte and Catholyte Types of Water, European Journal of Molecular Biotechnology, Vol. 7 No. 1, pp. 12-26.

Cayemitte, P. E. et al. (2021) Study of the Antibacterial Potency of Electroactivated Solutions of Calcium Lactate and Calcium Ascorbate on Bacillus cereus ATCC 14579 Vegetative Cells, ACS Omega 2022, 7, 4, 3579–3595.
https://pubs.acs.org/doi/abs/10.1021/acsomega.1c06124

Cited:
Gluhchev, G., Ignatov, I., Karadzhov, S., Miloshev, G., Ivanov, N., Mosin, O.V. (2015) Studying the Antimicrobial and Antiviral Effects of Electrochemically Activated NaCl Solutions of Anolyte and Catholyte on a Strain of E. Coli DH5 and Classical Swine Fever (CSF) Virus, European Journal of Medicine, 9 (3), 124-138.

USBEKISTAN
Ravshanov, S., Isabaev, I. (2021) Chemistry and Chemical Engineering, Activation of Water Used in the Preparartion of Wheat Grain for Varietal Milling, No. 4.
https://uzjournals.edu.uz/cce/vol2021/iss4/10/

Cited:
Gluhchev, G, Ignatov, I., Karadzhov, S., Miloshev, G., Ivanov, N., Mosin, O.V. (2015) Electrochemically Activited Water: Biophysical and Biological Effects of
Anolyte and Catholyte Types of Water, European Journal of Molecular Biotechnology, Vol. 7 No. 1, pp. 12-26.

BRASIL
Viela, A. L. O., de Rosa, S. O. V., F., Coelho, S. V. B. (2021) Antioxidant and antimicrobial activity of cathode and anode water in Coffea arabica L. seeds, J. Seed Sci., Vol. 43.
https://www.scielo.br/j/jss/a/69VLhzSWHtPybm3z5TPMFkS/?lang=en&amp;format=html

Cited:
Ignatov, I., Mosin, O. V., Gluhchev, G., Karadzhov, S., Miloshev, G., Ivanov, N., (2015) Studying Electrochemically Activated NaCl Solutions of Anolyte and Catholyte by Methods of Non-Equilibrium Energy Spectrum (NES) and Differential Non-Equilibrium Energy Spectrum (DNES), Journal of Medicine, Physiology and Biophysics, 14, 6-18.

UKRAINE
Aidarbekova, S., Aider, M. (2022) Production of Ryazhenka, a traditional Ukrainian fermented baked milk, by using electro-activated whey as supplementing ingredient and source of lactulose, Food Bioscience, 46.
https://www.sciencedirect.com/science/article/abs/pii/S2212429221006519

Cited:
Ignatov I, Gluhchev G, Karadzhov S, Miloshev G, Ivanov N, Mosin O.V. (2015) Preparation of electrochemically activated water solutions (catholyte/anolyte) and studying their physical- chemical properties. J Health Med Nurs 13, 64–78.

TURKEY
ÇELİK, S., AKYÜZ, S., ÖZEL, A. E., TURHAN, M. (2020) Raman Spectroscopy Investigation of the Effect of Electrical Stimulation on Destroying Lipid Membrane of Viruses, Eurasian Business &amp; Economics Journal, 23, 84-89.
https://www.avbbio.com/images/Atom-ingilizce.pdf

Cited:
Gluhchev, G., Ivanov, N., Ignatov, I., Karadzhov, S., Miloshev, G., Mosin, O. V. (2015) Virucidal and Bactericidal Effects of Electrochemically Anolyte and Catholyte Types of Water on Classical Swine Fever Virus and Bacterium E. Coli DH5, Water: Hygiene and Ecology, No. 1-2 (3): 3-10.