A Mathematical Model for Two Solutes Transport in a Poroelastic Material and Its Applications

arXiv - QuanBio - Tissues and Organs Pub Date : 2024-03-01 DOI:arxiv-2403.00216

Roman Cherniha, Joanna Stachowska-Pietka, Jacek Waniewski

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Abstract

Using well-known mathematical foundations of the elasticity theory, a mathematical model for two solutes transport in a poroelastic material (soft tissue is a typical example) is suggested. It is assumed that molecules of essentially different sizes dissolved in fluid and are transported through pores of different sizes. The stress tensor, the main force leading to the material deformation, is taken not only in the standard linear form but also with an additional nonlinear part. The model is constructed in 1D space and consists of six nonlinear equations. It is shown that the governing equations are integrable in stationary case, therefore all steady-state solutions are constructed. The obtained solutions are used in an example for healthy and tumour tissue, in particular, tissue displacements are calculated and compared for parameters taken from experimental data in cases of the linear and nonlinear stress tensors. Since the governing equations are non-integrable in non-stationary case, the Lie symmetry analysis is used in order to construct time-dependent exact solutions. Depending on parameters arising in the governing equations, several special cases with non-trivial Lie symmetries are identified. As a result, multi-parameter families of exact solutions are constructed including those in terms of special functions(hypergeometric and Bessel functions). A possible application of the solutions obtained is demonstrated.

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多孔弹性材料中两种溶质迁移的数学模型及其应用

利用众所周知的弹性理论数学基础，提出了一种在孔弹性材料（软组织是一个典型例子）中传输两种溶质的数学模型。假设大小基本不同的分子溶解在流体中，并通过大小不同的孔隙传输。应力张量是导致材料变形的主要作用力，不仅采用标准线性形式，还增加了非线性部分。该模型在一维空间中构建，由六个非线性方程组成。结果表明，在静态情况下，控制方程是可积分的，因此可以构建所有稳态解。所得到的解被用于健康组织和肿瘤组织的实例中，特别是在线性和非线性应力张量的情况下，组织位移的计算和与实验数据参数的比较。由于控制方程在非稳态情况下是不可解的，因此使用了李对称分析来构建与时间相关的精确解。根据控制方程中出现的参数，确定了几种具有非三维李对称性的特殊情况。因此，构建了精确解的多参数族，包括以特殊函数（超几何函数和贝塞尔函数）表示的解。演示了所获解的可能应用。

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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arXiv - QuanBio - Tissues and Organs

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