Evaluation of the Interaction of Cold Atmospheric Plasma of a Dielectric Barrier Discharge with the Surface of Various Materials and Biological Objects
https://doi.org/10.35596/1729-7648-2026-24-1-91-99
Abstract
The application of plasma technologies in engineering, and particularly in healthcare, requires assessing the impact and interaction of plasma with material surfaces. This article presents developed methods for reliably monitoring the plasma state and its interaction with the surface of objects, ensuring the reproducibility of technological processes for surface treatment of materials and therapeutic procedures, as well as expanded opportunities for increasing the efficiency of plasma technologies in healthcare. An assessment of the impact of plasma on the surface of various organic and inorganic materials, biological tissues, and an assessment of the interaction with them was carried out. For a qualitative and quantitative assessment, it is proposed to use the volt-ampere characteristics and the power released inthe “plasma-object” load. It has been established that the power released at the load during interaction with cold plasma depends on the material being exposed to the plasma. This parameter must be monitored when processing materials and biological tissues. It is shown that there are differences in the values of active power released at the electrodes of the discharge system for biological tissue samples (subcutaneous fat and muscle tissue). Moreover, this difference increases with increasing output voltage.
About the Authors
A. OsipovBelarus
Osipov Anatoly - Cand. Sci. (Tech.), Associate Professor, Head of the Sectoral Laboratory at the Center for “Devices, Systems and Technologies for Medical Purposes”
220013, Minsk, P. Brovki St., 6
Tel.: +375 17 293-86-41
T. Ma
Belarus
Tianbao Ma - Junior Research Fellow at an Industry Laboratory of the Center for “Devices, Systems and Techno logies for Medical Purposes”
Minsk
M. Tumilovich
Belarus
Miraslau Tumilovich - Dr. Sci. (Tech.), Professor, Professor of the Department of Electronic Engineering and Technology
Minsk
A. Patseyev
Belarus
Alexandr Patseyev - Chief Physician
Minsk
S. Patseyeu
Belarus
Searhei Patseyeu - Director
Minsk
References
1. Reema, Ruchel Khanikar R., Bailung H., Sankaranarayanan K. (2022) Review of the Cold Atmospheric Plasma Technology Application in Food, Disinfection, and Textiles: A Way Forward for Achieving Circular Eco nomy. Frontiers in Physics. 10. https://doi.org/10.3389/fphy.2022.942952.
2. Kozyreva V. O. (2022) Plasma Medicine: Prospects and Experience of Using Low-Temperature Argon Plasma in Medical Rehabilitation. Physiotherapy, Balneology and Rehabilitation. 21 (5), 359–367. https://doi.org/10.17816/rjpbr115273 (in Russian).
3. Weltmann K. D., von Woedtke T. (2016) Plasma Medicine – Current State of Research and Medical Application. Plasma Physics and Controlled Fusion. 59 (1). https://doi.org/10.1088/0741-3335/59/1/014031.
4. Toyokuni S., Ikehara Y., Kikkawa F., Hori M. (2018) Plasma Medical Science. Cambridge, Academic Press Publ.
5. Laroussi M., Lu X., Keidar M. (2017) Perspective: The Physics, Diagnostics, And Applications of Atmosphe ric Pressure Low Temperature Plasma Sources Used in Plasma Medicine. Journal of Applied Physics. 122 (4). https://doi.org/10.1063/1.4993710.
6. Weltmann K. D., Kolb J. F., Holub M., Uhrlandt D., Šimek M., Ostrikov K., et al. (2019) The Future for Plasma Science and Technology. Plasma Processes and Polymers. 16 (1). https://doi.org/10.1002/ppap.201800118.
7. Osipov A. N., Ma Т., Rokach V. A. (2025) Analysis of Electrical Signals Exciting Low-Temperature Atmospheric Plasma of Dielectric Barrier Discharge. Doklady BGUIR. 23 (2), 44–52. https://doi.org/10.35596/1729-7648-2025-23-2-44-52 (in Russian).
8. Tianbao Mа, Kalenkovich Ya., Rokach V., Osipov A. (2025) Generation of Low-Temperature Plasma by Pulse-Width Modulated Signals and Monitoring of the Interaction with the Surface of Objects. Plasma Science and Technology. 27 (1).
9. Bessonov L. A. (1996) Theoretical Foundations of Electrical Engineering. Electrical Circuits. Moscow, Gra duate School Publ. (in Russian).
Review
For citations:
Osipov A., Ma T., Tumilovich M., Patseyev A., Patseyeu S. Evaluation of the Interaction of Cold Atmospheric Plasma of a Dielectric Barrier Discharge with the Surface of Various Materials and Biological Objects. Doklady BGUIR. 2026;24(1):91-99. (In Russ.) https://doi.org/10.35596/1729-7648-2026-24-1-91-99
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