A New Technology of Bactericidal Processing of Koch’s Bacillus on the Basis of Pulsed Electromagnetic Radiation
Електронного архіву Харківського національного університету радіоелектроніки (Open Access Repository of KHNURE)
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Title |
A New Technology of Bactericidal Processing of Koch’s Bacillus on the Basis of Pulsed Electromagnetic Radiation
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Creator |
Chumakov, V. I.
Taranchuk, A. Stetsiuk, V. Stetsiuk, V. |
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Subject |
Keywords—capacitive storage; forplasma; magneto-plasma compressor; hard ultraviolet; pulse sterilizer; biomedical technologies; bactericidal and sterilizing processin; Koch’s bacillus
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Description |
[1] MJ. Alfa, P. DeGagne, N. Olson, R. Hizon, “Comparison of liquid chemical sterilization with peracetic acid and ethylene oxide sterilization for long narrow lumens”, American Journal of Infection Control, 1998, vol. 26(5), p. 469-477. [2] Abigail Phipps, Edward Vaynshteyn, John B. Kowalski, Manh- Dan Ngo, Karen Merritt, Joel Osborne, Evangelia Chnari, “Chemical sterilization of allograft dermal tissues”, Cell and Tissue Banking, December 2017, vol. 18, issue 4, p. 573-584. [3] WA. Rutala, DJ. Weber, “Clinical effectiveness of low-temperature sterilization technologies”, Infection Control and Hospital Epidemiology, 1998, vol.19(10), p. 798-804. [4] WA. Rutala, MF. Gergen, DJ. Weber, “Comparative evaluation of the sporicidal activity of new low-temperature sterilization technologies: Ethylene oxide, 2 plasma sterilization systems, and liquid peracetic acid”, American Journal of Infection Control, 1998, vol. 26(4), p. 393-398. [5] SG. Akterian, PS. Fernandez, ME. Hendrickx, PP. Tobback, PM. Periago, A. Martinez, “Risk analysis of the thermal sterilization process. Analysis of factors affecting the thermal resistance of microorganisms”, Int. J. Food Microbiol, 1999, Mar 1, vol. 47(1-2), pp. 51-7. [6] M. Moisan, J. Barbeau, S. Moreau, J. Pelletier, Mtabrizian, L. H. Yahia, “Low-temperature sterilization using gas plasmas: a review of the experiments and an analysis of the inactivation mechanisms”, Int. Journal of Pharmaceutics, September 2001, vol. 226 (1–2), pp. 1-21. [7] N. Selcan Türker, A. Yekta Özer, Burak Kutlu, Rahime Nohutcu, Arzu Sungur, Hasan Bilgili, Melike Ekizoglu, Meral Özalp, “The effect of gamma radiation sterilization on dental biomaterials”, Tissue Engineering and Regenerative Medicine, October 2014, vol. 11, issue 5, pp. 341-349. [8] Mercury Vapor banned in 2008; S.10 Energy Policy Act of 2005. Mercuryvaporlight.com. Retrieved on 2012-01-02. [9] J. U. Neuber, M. A. Malik, “Nanosecond pulsed plasma brush for bacterial inactivation on laminate”, IEEE Trans. on Radiation and Plasma Medical Sciences, vol. 1, 2017, pp. 368-375. Mounir Laroussi, “The Biomedical Applications of Plasma: “A Brief History of the Development of a New Field of Research”, IEEE Trans. on Plasma Science, 2008, vol. 36, issue: 4, pp: 1612 – 1614. [10] Mounir Laroussi, "Low-Temperature Plasmas for Medicine?", Plasma Science IEEE Trans., vol. 37, pp. 714-725, 2009, ISSN 0093-3813. [11] Y. H. Usta, U. K. Ercan, “Development of a portable cold atmospheric plasma device for infected wound management”, [Medical Technologies National Congress (TIPTEKNO), Trabzon, Turkey. 12-14 Oct.], 2017, pp. 1-4. [12] Shen-Bin Wu, Chih-Hung Liu, Mei-Chih Wang. Chung-Ping Chiang, Chan-Hsing Lo, “Bactericidal applications of low temperature atmospheric pressure plasma in dental care” [IEEE Int. Conf. on Plasma Science (ICOPS), San Francisco, USA], 2013. p. 1. [13] Patent 104719 (UA). V. Chumakov; M. Ostryzhnyy; A. Stolyarchuk; S. Pidchenko; A. Taranchuk; O. Kharchenko; A. Pron'; Yu. Virstyuk, “Рulse sterilizer” . [14] V. I. Chumakov, K. V. Korytchenko, Yu. Ya. Volkolupov, M. A. Krasnogolovets, M. A. Ostrizhnoi, “Shock wave strength and discharge energy in gases”, Technical Physics, vol. 47, 1 April 2002, pp. 495-496. [15] A. Yegorov, A. Lonin, V. Chumakov, A. Shepelev, O. Nemashkalo “Non-ionizing electromagnetic radiation and ecology”, Telecommunications and Radio Engineering, Т. 69, 2010, Issue: 8, pp. 733-750, ISSN: 0040-2508. [16] V. I. Chumakov, Yu. Ya. Volkolupov, M. A. Krasnogolovets, M. A. Ostrizhnoi, V. G. Nesterenko, O. I. Kharchenko, “Results of visual investigations of the magnetoplasma compressor emission in air”/ Technical Physics, vol. 46, 8, August 2001, pp. 1040-1044. [17] Y.Y. Volkolupov, V.I. Chumakov, M.A. Ostrizhnoy, M.A. Krasnogolovets, T.A. Semenets, “Simplified algorithm of electrostatic fields analysis” [29th IEEE International Conference Record- Abstracts on Plasma Science, Banff, Alberta, Canada, 26-30 May, 2002], p.220. [18] Yu .F. Lonin, V.I. Chumakov, M.A.Ostrizhnoy, A.Yu. Zvyagintsev, K.R. Neezhmakov, “Estimation of characteristics of radiation of the powerful pulse broadband optical source”, Problems of Atomic Science and Technology, 2008. Abstract— The technology of bactericidal and sterilizing processing of Koch’s Bacillus on the basis of pulsed electromagnetic ultraviolet (UV) radiation has been proposed. This technology is based on the pulse method of bactericidal processing of objects with low-temperature plasma using pulse sterilizer developed by the authors. The mathematical model of generating broadband pulsed radiation by the source of powerful optical radiation, based on the technique of charged particles accelerator, has been developed. The structure of the electromagnetic radiation source of the high-intensity optical range has been presented. The research of the bactericidal effect of pulsed UV radiation on Koch’s bacillus has been conducted. |
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Date |
2018-06-14T17:56:25Z
2018-06-14T17:56:25Z 2018 |
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Type |
Article
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Identifier |
V. Chumakov A. Taranchuk, V. Stetsiuk, V. Michan. 2018 IEEE 38th International Conference on Electronics and Nanotechnology (ELNANO), p. 271-273
http://openarchive.nure.ua/handle/document/6186 |
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Language |
en_US
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