LOW-TEMPERATURE ATMOSPHERIC-PRESSURE PLASMA IN MICROBIAL DECONTAMINATION AND MEAT TECHNOLOGY. A REVIEW-Reference-Cited by-同舟云学术

LOW-TEMPERATURE ATMOSPHERIC-PRESSURE PLASMA IN MICROBIAL DECONTAMINATION AND MEAT TECHNOLOGY. A REVIEW

Published:2019-04-05 Issue:1 Volume:4 Page:21-29
ISSN:2414-441X
Container-title:Theory and practice of meat processing
language:
Short-container-title:Teor. prakt. pererab. mâsa (Print)

Author:

Gorbunova Natalia A.¹

Affiliation:

1. V.M. Gorbatov Federal Research Center for Food Systems of Russian Academy of Sciences

Abstract

The development of plasma technology is associated with the unique features of non-equilibrium low-temperature plasma: high electron energy and high concentration of chemically active excited and charged particles at low gas temperature, which allows to process thermolabile materials and biological objects in gentle conditions when high temperatures are not required. The biological effects of low-temperature plasma exposure are considered. It was established that during plasma treatment, a combined effect on cells and tissues of living systems from UV radiation, ions and chemically active particles occurs. Depending on the plasma type, the significance of each of the listed mechanisms for increasing the effectiveness of plasma treatment may vary. However, all these mechanisms interact with each other and have a synergistic effect. It was shown that the conducted studies confirm the ability of low-temperature plasma to inactivate pathogenic microorganisms upon contact with biological objects and foods. The results of the studies are presented, the purpose of which was to study the effect of plasma treatment on nitrite concentration in the water treated by this method and to assess the possibility of its use as a source of nitrite when curing meat products.

Publisher

The Gorbatov's All-Russian Meat Research Institute

Reference53 articles.

1. Advanced cold plasma technology. NPC «Plasma», 2016. [Electronic resource: http://plasmamed.ru/application/ files/8114/8828/3627/RUS-PRESENTATION-NPC_Plasma_ investors.pdf . Access date: 09.10.2018]. (In Russian)

2. Tikhonov, E.A. (2013). Investigation of the influence of cold plasma treated water on potato planting growth intensity and productivity. Polythematic online scientific journal of Kuban State Agrarian University, 85, 363-373. (In Russian)

3. Ur’eva, A. V., Kovalchuk, A.N. (2014). Introduction to plasma technology and hydrogen energy: a tutorial. Tomsk: Tomsk Polytechnic University. – 90 p. (In Russian)

4. Fridman, G., Friedman, G., Gutsol, A., Shekhter, A.B, Vasilets, V.N., Fridman, A. (2008). Applied Plasma Medicine. Plasma Processes and Polymers, 5(6), 503–533. DOI: 10.1002/ ppap.200700154

5. Avdeev, S.M., Kuznetsova, E.A., Sosnin, E.A. Plasma treatment of atmospheric pressure of contaminated Escherichia coli surfaces. [Electronic resource: http://asf.ural.ru/VNKSF/Uchastniki/ vnksf11/tezis/04/AvdeevSM/AvdeevSM.html. Access date: 09.10.2018]. (In Russian)

Cited by 3 articles. 订阅此论文施引文献订阅此论文施引文献，注册后可以免费订阅5篇论文的施引文献，订阅后可以查看论文全部施引文献

1. Challenges and opportunities of non-conventional technologies concerning food safety;World's Poultry Science Journal;2023-01-02

2. Non-thermal Plasma Treatment of ESKAPE Pathogens: A Review;Frontiers in Microbiology;2021-10-12

3. The effect of mixed electric field on characteristic of Ar–N2 plasma jets for TiN surface treatment;Journal of Physics D: Applied Physics;2020-01-06