生物膜力学和模式

Ana Carpio, Elena Cebrian, David R. Espeso, Perfecto Vidal
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引用次数: 0

摘要

从多细胞组织到细菌群落,三维细胞结构都是在细胞活动和机械力的相互作用下产生的。简单的细菌群落为分析这种相互作用提供了模型系统。生物膜是附着在潮湿表面上的细菌聚集体,并被包裹在自身产生的聚合物基质中。流动中的生物膜形成丝状结构,与在空气/固体表面观察到的皱褶层形成鲜明对比。我们能够通过弹性杆和板模型再现这两种类型的形状,这些模型结合了生物质产生和分化过程中的信息,如生长率、生长张量或内应力,以及与环境相互作用的约束条件。要对生物膜动力学进行更精确的研究,就必须解决生物膜从周围环境中吸水以及生物系统内部流体传输的问题。这一过程会改变生物膜的材料特性和整体应力。我们分析了孔弹性方法是否能对类流体和类固体生物膜行为提供合适的综合描述。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Biofilm mechanics and patterns
From multicellular tissues to bacterial colonies, three dimensional cellular structures arise through the interaction of cellular activities and mechanical forces. Simple bacterial communities provide model systems for analyzing such interaction. Biofilms are bacterial aggregates attached to wet surfaces and encased in a self-produced polymeric matrix. Biofilms in flows form filamentary structures that contrast with the wrinkled layers observed on air/solid interfaces. We are able to reproduce both types of shapes through elastic rod and plate models that incorporate information from the biomass production and differentiations process, such as growth rates, growth tensors or inner stresses, as well as constraints imposed by the interaction with environment. A more precise study of biofilm dynamics requires tackling water absorption from its surroundings and fluid transport within the biological system. This process alters the material properties of the biofilm and the overall stresses. We analyze whether poroelastic approaches can provide a suitable combined description of fluid-like and solid-like biofilm behavior.
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