Antibacterial Effects of Low-temperature Plasma Generated by Atmospheric-pressure Plasma Jet Are mediated by Reactive Oxygen Species

Overview

Journal Sci Rep

Specialty Science

Date 2020 Feb 22

PMID 32080228

Citations 43

Authors

McKayla J Nicol

Timothy R Brubaker

Brian J Honish 2nd

Alyssa N Simmons

Ali Kazemi

Madison A Geissel

Connor T Whalen

Christopher A Siedlecki

Sven G Bilen

Sean D Knecht

Girish S Kirimanjeswara

Affiliations

Soon will be listed here.

Abstract

Emergence and spread of antibiotic resistance calls for development of non-chemical treatment options for bacterial infections. Plasma medicine applies low-temperature plasma (LTP) physics to address biomedical problems such as wound healing and tumor suppression. LTP has also been used for surface disinfection. However, there is still much to be learned regarding the effectiveness of LTP on bacteria in suspension in liquids, and especially on porous surfaces. We investigated the efficacy of LTP treatments against bacteria using an atmospheric-pressure plasma jet and show that LTP treatments have the ability to inhibit both gram-positive (S. aureus) and gram-negative (E. coli) bacteria on solid and porous surfaces. Additionally, both direct LTP treatment and plasma-activated media were effective against the bacteria suspended in liquid culture. Our data indicate that reactive oxygen species are the key mediators of the bactericidal effects of LTP and hydrogen peroxide is necessary but not sufficient for antibacterial effects. In addition, our data suggests that bacteria exposed to LTP do not develop resistance to further treatment with LTP. These findings suggest that this novel atmospheric-pressure plasma jet could be used as a potential alternative to antibiotic treatments in vivo.

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