Plasma activated water pre-treatment substantially enhances phage activity against Proteus mirabilis biofilms

IF 5.9 Q1 MICROBIOLOGY
Akash Shambharkar , Thomas P. Thompson , Laura A. McClenaghan , Paula Bourke , Brendan F. Gilmore , Timofey Skvortsov
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Abstract

The ongoing antimicrobial resistance crisis has incentivised research into alternative antibacterial and antibiofilm agents. One of them is plasma-activated water (PAW), which is produced by exposing water to a cold plasma discharge. This process generates a diverse array of reactive oxygen and nitrogen species (ROS/RNS) with antimicrobial properties. Another intensively studied class of alternative antimicrobials are bacteriophages, attracting attention due to their specificity and strong antibacterial activity. As combinations of different types of antimicrobials are known to often exhibit synergistic interactions, in this study we investigated the combined use of cold atmospheric-pressure plasma-activated water and the bacteriophage vB_PmiS_PM-CJR against Proteus mirabilis biofilms as a potential option for treatment of catheter-associated urinary tract infections (CAUTIs).
We compared the effect of two cold plasma discharge setups for PAW production on its antimicrobial efficacy against P. mirabilis planktonic and biofilm cultures. Next, we assessed the stability of the phage vB_PmiS_PM-CJR in PAW. Finally, we tested the antimicrobial activity of the phages and PAW against biofilms, both individually and in combinations.
Our findings demonstrate that the combination of PAW with phage is more effective against biofilms compared to individual treatments, being able to reduce the number of biofilm-embedded cells by approximately 4 log. We were also able to show that the order of treatment plays an important role in the anti-biofilm activity of the phage-PAW combination, as the exposure of the biofilm to PAW prior to phage administration results in a stronger effect than the reverse order.
This research underlines PAW's ability to potentiate phage activity, showcasing a considerable reduction in biofilm viability and biomass. Additionally, it contributes to the growing body of evidence supporting the use of phage-based combinatorial treatments. Overall, this sequential treatment strategy demonstrates the potential of leveraging multiple approaches to address the mounting challenge of antibiotic resistance and offers a promising avenue for enhancing the efficacy of CAUTI management.
等离子体活化水预处理大大提高了噬菌体抗变形杆菌生物膜的活性
当前的抗菌药耐药性危机促使人们对替代抗菌剂和抗生物膜剂进行研究。其中之一就是等离子活化水(PAW),它是通过将水暴露于冷等离子体放电而产生的。这一过程会产生多种具有抗菌特性的活性氧和氮物种(ROS/RNS)。另一类受到深入研究的替代抗菌剂是噬菌体,因其特异性和强大的抗菌活性而备受关注。众所周知,不同类型抗菌剂的组合往往会产生协同作用,因此在本研究中,我们研究了联合使用低温常压等离子活化水和噬菌体 vB_PmiS_PM-CJR 来抗击奇异变形杆菌生物膜,以此作为治疗导管相关性尿路感染(CAUTIs)的一种潜在选择。我们比较了用于生产 PAW 的两种冷等离子放电设置对其对奇异变形杆菌浮游生物和生物膜培养物的抗菌效果的影响。接下来,我们评估了 vB_PmiS_PM-CJR 噬菌体在 PAW 中的稳定性。最后,我们测试了噬菌体和 PAW 单独或组合对生物膜的抗菌活性。我们的研究结果表明,与单独处理相比,PAW 与噬菌体的组合对生物膜更有效,能将生物膜嵌入细胞的数量减少约 4 log。我们还能证明,处理顺序在噬菌体-PAW 组合的抗生物膜活性中起着重要作用,因为在施用噬菌体之前将生物膜暴露于 PAW 会比相反的顺序产生更强的效果。此外,越来越多的证据支持使用基于噬菌体的组合疗法,这项研究也为此做出了贡献。总之,这种连续治疗策略展示了利用多种方法应对日益严重的抗生素耐药性挑战的潜力,并为提高 CAUTI 治疗效果提供了一条前景广阔的途径。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Biofilm
Biofilm MICROBIOLOGY-
CiteScore
7.50
自引率
1.50%
发文量
30
审稿时长
57 days
期刊介绍:
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