Physical Parameters of Arterial Thrombus as a Porous Medium

IF 4.033 Q4 Biochemistry, Genetics and Molecular Biology

Biophysics Pub Date : 2024-07-04 DOI:10.1134/s0006350924700155

E. S. Bershadsky, D. Yu. Nechipurenko

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Abstract

The formation of a hemostatic thrombus is a key response of the hemostatic system to a wide range of possible vascular damage. The main mechanism of thrombus growth in conditions of high shear rates is platelet adhesion and aggregation. It is known that arterial thrombi have significant spatial heterogeneity, which is associated with the heterogeneity of the distribution of platelet activators in the thrombus structure. The spatiotemporal dynamics of the molecules involved in thrombosis depends on the parameters of the transfer of these substances in the thrombus. To study the dynamics of arterial blood thrombi formation, continuum models representing a blood thrombus as a porous medium are actively used today. However, when choosing the parameters of such models, researchers face significant uncertainty caused by conflicting experimental data. This review analyzes the published data on the physical parameters of an arterial thrombus as a porous medium. Special attention is paid to the analysis of parameters for the external part of the thrombus, the so-called shell, which is generally characterized by higher values of porosity and permeability.

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作为多孔介质的动脉血栓的物理参数

止血血栓的形成是止血系统对各种可能的血管损伤做出的关键反应。高剪切率条件下血栓生长的主要机制是血小板的粘附和聚集。众所周知，动脉血栓具有明显的空间异质性，这与血小板激活剂在血栓结构中分布的异质性有关。参与血栓形成的分子的时空动态取决于这些物质在血栓中的转移参数。为了研究动脉血栓形成的动力学，将血栓表示为多孔介质的连续体模型如今被广泛使用。然而，在选择此类模型的参数时，研究人员面临着因实验数据相互矛盾而造成的巨大不确定性。这篇综述分析了已发表的关于作为多孔介质的动脉血栓物理参数的数据。其中特别关注血栓外部（即所谓的外壳）的参数分析，外壳的特点通常是孔隙率和渗透率值较高。

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

Biophysics Biochemistry, Genetics and Molecular Biology-Biophysics

CiteScore

1.20

自引率

0.00%

发文量

期刊介绍： Biophysics is a multidisciplinary international peer reviewed journal that covers a wide scope of problems related to the main physical mechanisms of processes taking place at different organization levels in biosystems. It includes structure and dynamics of macromolecules, cells and tissues; the influence of environment; energy transformation and transfer; thermodynamics; biological motility; population dynamics and cell differentiation modeling; biomechanics and tissue rheology; nonlinear phenomena, mathematical and cybernetics modeling of complex systems; and computational biology. The journal publishes short communications devoted and review articles.

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