Delivery and quantification of hydrogen peroxide generated via cold atmospheric pressure plasma through biological material
Delivery and quantification of hydrogen peroxide generated via cold atmospheric pressure plasma through biological material
The ability of plasma-generated hydrogen peroxide (H2O2) to traverse bacterial biofilms and the subsequent fate of the generated H2O2 has been investigated. An in vitro model, comprising a nanoporous membrane impregnated with artificial wound fluid and biofilms of varying maturity was treated with a helium-driven, cold atmospheric pressure plasma (CAP) jet. The concentration of H2O2 generated below the biofilms was quantified. The results showed that the plasma-generated H2O2 interacted significantly with the biofilm, thus exhibiting a reduction in concentration across the underlying nanoporous membrane. Biofilm maturity exhibited a significant effect on the penetration depth of H2O2, suggesting that well established, multilayer biofilms are likely to offer a shielding effect with respect to cells located in the lower layers of the biofilm, thus rendering them less susceptible to plasma disinfection. This may prove clinically significant in the plasma treatment of chronic, deep tissue infections such as diabetic and venous leg ulcers. Our results are discussed in the context of plasma-biofilm interactions, with respect to the fate of the longer lived reactive species generated by CAP, such as H2O2.
Hathaway, Hollie J.
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Patenall, Bethany Lee
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Thet, Naing T.
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Sedgwick, Adam C.
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Williams, George
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Jenkins, A. Toby A.
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Allinson, S.L.
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Short, Robert D.
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Hathaway, Hollie J.
acc628f7-b28d-4e53-9771-5aff4ecf88f5
Patenall, Bethany Lee
6307b448-a628-4242-bec2-b7dd2ac7d21a
Thet, Naing T.
ce91e7c9-d39d-431b-bd64-e7e97e9f8541
Sedgwick, Adam C.
7329dac0-8976-4885-bbe9-6edb9d1ab017
Williams, George
26810522-92ef-4b61-a766-582bf15be280
Jenkins, A. Toby A.
e0e4ebe3-c2d6-4aae-81eb-66923f6f98dd
Allinson, S.L.
dc35efa2-6bfe-41b6-a89f-812f7070e151
Short, Robert D.
cf0e8818-206d-4abd-ba31-b0c3d870d626
Hathaway, Hollie J., Patenall, Bethany Lee, Thet, Naing T., Sedgwick, Adam C., Williams, George, Jenkins, A. Toby A., Allinson, S.L. and Short, Robert D.
(2021)
Delivery and quantification of hydrogen peroxide generated via cold atmospheric pressure plasma through biological material.
Journal of Physics D: Applied Physics, 52, [505203].
(doi:10.1088/1361-6463/ab4539).
Abstract
The ability of plasma-generated hydrogen peroxide (H2O2) to traverse bacterial biofilms and the subsequent fate of the generated H2O2 has been investigated. An in vitro model, comprising a nanoporous membrane impregnated with artificial wound fluid and biofilms of varying maturity was treated with a helium-driven, cold atmospheric pressure plasma (CAP) jet. The concentration of H2O2 generated below the biofilms was quantified. The results showed that the plasma-generated H2O2 interacted significantly with the biofilm, thus exhibiting a reduction in concentration across the underlying nanoporous membrane. Biofilm maturity exhibited a significant effect on the penetration depth of H2O2, suggesting that well established, multilayer biofilms are likely to offer a shielding effect with respect to cells located in the lower layers of the biofilm, thus rendering them less susceptible to plasma disinfection. This may prove clinically significant in the plasma treatment of chronic, deep tissue infections such as diabetic and venous leg ulcers. Our results are discussed in the context of plasma-biofilm interactions, with respect to the fate of the longer lived reactive species generated by CAP, such as H2O2.
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e-pub ahead of print date: 9 October 2021
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Local EPrints ID: 474147
URI: http://eprints.soton.ac.uk/id/eprint/474147
ISSN: 0022-3727
PURE UUID: 93edec9e-0068-4272-bbf3-cb72a886fca1
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Date deposited: 14 Feb 2023 17:40
Last modified: 17 Mar 2024 04:17
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Contributors
Author:
Hollie J. Hathaway
Author:
Bethany Lee Patenall
Author:
Naing T. Thet
Author:
Adam C. Sedgwick
Author:
George Williams
Author:
A. Toby A. Jenkins
Author:
S.L. Allinson
Author:
Robert D. Short
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