生物膜物理特性对抗生素敏感性的影响:低频超声波的影响。

IF 7.8 1区 生物学 Q1 BIOTECHNOLOGY & APPLIED MICROBIOLOGY
Yanina Nahum, Neila Gross, Albert Cerrone, Karel Matouš, Robert Nerenberg
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引用次数: 0

摘要

生物膜对抗菌药具有很强的抗药性,往往会导致慢性感染。将抗菌剂与低频超声(LFU)结合使用可提高抗菌效率,但人们对其基本机制知之甚少。生物膜的物理特性取决于生长条件和年龄等因素,会对灭活效率产生重大影响。在本研究中,我们研究了铜绿假单胞菌生物膜对妥布霉素的敏感性,以及是否经过 LFU 处理。生物膜分别在低剪切力和高剪切力条件下生长,以提供不同的特性。与高剪切生物膜相比,低剪切生物膜的厚度、粗糙度和孔隙率更大,密度更低。高剪切生物膜的生物膜基质中蛋白质与多糖的比率高出三倍,表明生物膜的硬度更大。生物膜蠕变顺应性的微流变测量结果也证明了这一点。对于不含 LFU 的低剪切力生物膜来说,经过 2 小时的处理后,生物膜内部区域的活力基本不受抗生素的影响。对于不含 LFU 的高剪切生物膜,需要更高的 LFU 强度才能达到类似的灭活效果。微流变测量显示,生物膜灭活曲线的变化与生物膜机械特性的变化密切相关。建模表明,LFU 改变了抗生素在生物膜内的扩散性,这可能是由于 "去黏附 "效应。总之,这项研究表明,生物膜的物理特性(如顺应性、形态)与抗菌效率有关。LFU 可削弱生物膜,同时增加其对抗生素的扩散性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Effect of biofilm physical characteristics on their susceptibility to antibiotics: impacts of low-frequency ultrasound.

Effect of biofilm physical characteristics on their susceptibility to antibiotics: impacts of low-frequency ultrasound.

Biofilms are highly resistant to antimicrobials, often causing chronic infections. Combining antimicrobials with low-frequency ultrasound (LFU) enhances antimicrobial efficiency, but little is known about the underlying mechanisms. Biofilm physical characteristics, which depend on factors such as growth conditions and age, can have significant effects on inactivation efficiency. In this study, we investigated the susceptibility of Pseudomonas aeruginosa biofilms to tobramycin, with and without LFU treatment. The biofilms were grown under low and high fluid shear to provide different characteristics. Low-shear biofilms exhibited greater thickness, roughness, and porosity and lower density, compared to high-shear biofilms. The biofilm matrix of the high-shear biofilms had a three times higher protein-to-polysaccharide ratio, suggesting greater biofilm stiffness. This was supported by microrheology measurements of biofilm creep compliance. For the low-shear biofilms without LFU, the viability of the biofilms in their inner regions was largely unaffected by the antibiotic after a 2-hour treatment. However, when tobramycin was combined with LFU, the inactivation for the entire biofilm increased to 80% after 2 h. For the high-shear biofilms without LFU, higher LFU intensities were needed to achieve similar inactivation results. Microrheology measurements revealed that changes in biofilm inactivation profiles were closely related to changes in biofilm mechanical properties. Modeling suggests that LFU changes antibiotic diffusivity within the biofilm, probably due to a "decohesion" effect. Overall, this research suggests that biofilm physical characteristics (e.g., compliance, morphology) are linked to antimicrobial efficiency. LFU weakens the biofilm while increasing its diffusivity for antibiotics.

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来源期刊
npj Biofilms and Microbiomes
npj Biofilms and Microbiomes Immunology and Microbiology-Microbiology
CiteScore
12.10
自引率
3.30%
发文量
91
审稿时长
9 weeks
期刊介绍: npj Biofilms and Microbiomes is a comprehensive platform that promotes research on biofilms and microbiomes across various scientific disciplines. The journal facilitates cross-disciplinary discussions to enhance our understanding of the biology, ecology, and communal functions of biofilms, populations, and communities. It also focuses on applications in the medical, environmental, and engineering domains. The scope of the journal encompasses all aspects of the field, ranging from cell-cell communication and single cell interactions to the microbiomes of humans, animals, plants, and natural and built environments. The journal also welcomes research on the virome, phageome, mycome, and fungome. It publishes both applied science and theoretical work. As an open access and interdisciplinary journal, its primary goal is to publish significant scientific advancements in microbial biofilms and microbiomes. The journal enables discussions that span multiple disciplines and contributes to our understanding of the social behavior of microbial biofilm populations and communities, and their impact on life, human health, and the environment.
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