在高剪切应力下形成生物膜可增强对化学和机械挑战的耐受性。

Biofilm formation under high shear stress increases resilience to chemical and mechanical challenges.

作者信息

Simões L C, Gomes I B, Sousa H, Borges A, Simões M

机构信息

CEB-Centre of Biological Engineering, University of Minho, Braga, Portugal.

LEPABE, Department of Chemical Engineering, Faculty of Engineering, University of Porto, Porto, Portugal.

出版信息

Biofouling. 2022 Jan;38(1):1-12. doi: 10.1080/08927014.2021.2006189. Epub 2021 Nov 24.

DOI:10.1080/08927014.2021.2006189

PMID:34818957

Abstract

The effect that the hydrodynamic conditions under which biofilms are formed has on their persistence is still unknown. This study assessed the behaviour of biofilms, formed on stainless steel under different shear stress () conditions (1, 2 and 4Pa), to chemical (benzalkonium chloride - BAC, glutaraldehyde - GLUT and sodium hypochlorite - SHC) and mechanical (20Pa) treatments (alone and combined). The biofilms formed under different showed different structural characteristics. Those formed under a higher were invariably more tolerant to chemical and mechanical stresses. SHC was the biocide which caused the highest biofilm killing and removal, followed by BAC. The sequential exposure to biocides and mechanical stress was found to be insufficient for effective biofilm control. A basal layer containing biofilm cells mostly in a viable state remained on the surface of the cylinders, particularly for the 2 and 4Pa-generated biofilms.

摘要

生物膜形成时的流体动力学条件对其持久性的影响仍然未知。本研究评估了在不同剪切应力（1、2和4Pa）条件下在不锈钢上形成的生物膜对化学（苯扎氯铵 - BAC、戊二醛 - GLUT和次氯酸钠 - SHC）和机械（20Pa）处理（单独和联合）的反应。在不同剪切应力下形成的生物膜表现出不同的结构特征。在较高剪切应力下形成的生物膜对化学和机械应力的耐受性始终更高。SHC是导致生物膜杀灭和去除效果最佳的杀菌剂，其次是BAC。发现依次暴露于杀菌剂和机械应力不足以有效控制生物膜。圆柱体表面上仍残留有一层主要由存活状态生物膜细胞组成的基础层，特别是对于在2和4Pa下形成的生物膜。

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在高剪切应力下形成生物膜可增强对化学和机械挑战的耐受性。

Biofilm formation under high shear stress increases resilience to chemical and mechanical challenges.

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