Dispersion Inhibits Thermal Mitigation of Pseudomonas aeruginosa Biofilms on Self-Heating Surfaces

IF 4.6 3区生物学 Q2 MICROBIOLOGY

MicrobiologyOpen Pub Date : 2026-04-06 DOI:10.1002/mbo3.70283

Parham Parnian, Paraskevi K. Zoga, Haydar A. S. Aljaafari, Hannah Chicchelly, Michael Toops, Eric Nuxoll

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引用次数: 0

Abstract

Bacterial biofilms on medical implants are a major problem, typically requiring explantation and replacement of the biofilm-colonized implant. Thermal mitigation of these biofilms in situ has shown great promise in the laboratory, where the thermal shock can be most precisely delivered by immersion in hot media. Clinical implementation requires delivering the shock from the implant surface, however, leaving the surroundings at a cooler temperature. This study hypothesized that bacteria may rapidly, reversibly disperse into the cooler surroundings to partially evade the shock and tested this hypothesis by thermally shocking Pseudomonas aeruginosa biofilms on thermoelectric devices under media with different heat sink conditions. The time scale and equilibrium constant of this dispersion were investigated in ambient temperature immersion studies, and the effect of thermal shock on bacterial dispersion rate was investigated in a flow cell using biofilms grown on thermoelectric devices. The results showed that biofilms equilibrate with surrounding media in seconds, that a small fraction of bacteria in the biofilm are much less prone to dispersion, that thermal shock triggers an immediate increase in dispersion, and that shocking biofilms via their substrate in cooler surrounding decreases shock efficacy compared to shocks where the surrounding's temperature approaches that of the substrate.

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分散抑制铜绿假单胞菌生物膜在自加热表面的热缓解。

医学植入物上的细菌生物膜是一个主要问题，通常需要拔出和更换生物膜定植的植入物。这些生物膜的原位热缓解在实验室中显示出很大的前景，在实验室中，热冲击可以通过浸泡在热介质中最精确地传递。然而，临床应用需要从植入物表面传递电击，使周围环境处于较低的温度。本研究假设细菌可以快速、可逆地分散到较冷的环境中，以部分逃避冲击，并通过在不同散热条件下的介质上热冲击铜绿假单胞菌生物膜来验证这一假设。在环境温度浸泡实验中研究了这种分散的时间尺度和平衡常数，并利用在热电装置上生长的生物膜研究了热冲击对细菌分散速率的影响。结果表明，生物膜与周围介质在几秒钟内达到平衡，生物膜中的一小部分细菌不太容易分散，热冲击会立即增加分散，在较冷的环境中通过底物对生物膜进行冲击，与环境温度接近底物的冲击相比，会降低冲击效果。

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来源期刊

MicrobiologyOpen MICROBIOLOGY-

CiteScore

8.00

自引率

0.00%

发文量

审稿时长

20 weeks

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