A Hamilton principle-based model for diffusion-driven biofilm growth

IF 3 3区 医学 Q2 BIOPHYSICS
Felix Klempt, Meisam Soleimani, Peter Wriggers, Philipp Junker
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Abstract

Dense communities of bacteria, also known as biofilms, are ubiquitous in all of our everyday life. They are not only always surrounding us, but are also active inside our bodies, for example in the oral cavity. While some biofilms are beneficial or even necessary for human life, others can be harmful. Therefore, it is highly important to gain an in-depth understanding of biofilms which can be achieved by in vitro or in vivo experiments. Since these experiments are often time-consuming or expensive, in silico models have proven themselves to be a viable tool in assisting the description and analysis of these complicated processes. Current biofilm growth simulations are using mainly two approaches for describing the underlying models. The volumetric approach splits the deformation tensor into a growth and an elastic part. In this approach, the mass never changes, unless some additional constraints are enforced. The density-based approach, on the other hand, uses an evolution equation to update the growing tissue by adding mass. Here, the density stays constant, and no pressure is exerted. The in silico model presented in this work combines the two approaches. Thus, it is possible to capture stresses inside of the biofilm while adding mass. Since this approach is directly derived from Hamilton’s principle, it fulfills the first and second law of thermodynamics automatically, which other models need to be checked for separately. In this work, we show the derivation of the model as well as some selected numerical experiments. The numerical experiments show a good phenomenological agreement with what is to be expected from a growing biofilm. The numerical behavior is stable, and we are thus capable of solving complicated boundary value problems. In addition, the model is very reactive to different input parameters, thereby different behavior of various biofilms can be captured without modifying the model.

基于汉密尔顿原理的扩散驱动生物膜生长模型。
密集的细菌群落(也称为生物膜)在我们的日常生活中无处不在。它们不仅始终围绕着我们,而且还活跃在我们的体内,例如口腔中。有些生物膜对人类生活有益,甚至是必需的,而有些生物膜则可能有害。因此,通过体外或体内实验深入了解生物膜非常重要。由于这些实验往往耗时或昂贵,硅学模型已被证明是协助描述和分析这些复杂过程的可行工具。目前的生物膜生长模拟主要使用两种方法来描述基础模型。体积法将变形张量分为生长和弹性两部分。在这种方法中,质量永远不会改变,除非强制执行一些额外的约束条件。另一方面,基于密度的方法使用一个演化方程,通过增加质量来更新生长组织。在这种方法中,密度保持不变,也不会产生压力。本研究中提出的硅学模型结合了这两种方法。因此,可以在增加质量的同时捕捉生物膜内部的压力。由于这种方法是直接从汉密尔顿原理推导出来的,因此它能自动满足热力学第一和第二定律,而其他模型则需要单独检查。在这项工作中,我们展示了模型的推导以及一些选定的数值实验。数值实验结果表明,该模型与生长中的生物膜的预期现象非常吻合。数值行为是稳定的,因此我们能够解决复杂的边界值问题。此外,该模型对不同的输入参数反应灵敏,因此无需修改模型即可捕捉各种生物膜的不同行为。
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
Biomechanics and Modeling in Mechanobiology
Biomechanics and Modeling in Mechanobiology 工程技术-工程:生物医学
CiteScore
7.10
自引率
8.60%
发文量
119
审稿时长
6 months
期刊介绍: Mechanics regulates biological processes at the molecular, cellular, tissue, organ, and organism levels. A goal of this journal is to promote basic and applied research that integrates the expanding knowledge-bases in the allied fields of biomechanics and mechanobiology. Approaches may be experimental, theoretical, or computational; they may address phenomena at the nano, micro, or macrolevels. Of particular interest are investigations that (1) quantify the mechanical environment in which cells and matrix function in health, disease, or injury, (2) identify and quantify mechanosensitive responses and their mechanisms, (3) detail inter-relations between mechanics and biological processes such as growth, remodeling, adaptation, and repair, and (4) report discoveries that advance therapeutic and diagnostic procedures. Especially encouraged are analytical and computational models based on solid mechanics, fluid mechanics, or thermomechanics, and their interactions; also encouraged are reports of new experimental methods that expand measurement capabilities and new mathematical methods that facilitate analysis.
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