流下血管外损伤中血小板聚集的数学模型。

IF 1.9 4区数学 Q2 MATHEMATICS, INTERDISCIPLINARY APPLICATIONS

Multiscale Modeling & Simulation Pub Date : 2020-01-01 Epub Date: 2020-11-18 DOI:10.1137/20m1317785

Kathryn G Link, Matthew G Sorrells, Nicholas A Danes, Keith B Neeves, Karin Leiderman, Aaron L Fogelson

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引用次数: 0

摘要

我们首次提出了血管外损伤中流动介导的原发性止血数学模型，该模型可跟踪从最初沉积到闭塞的过程。该模型由描述血小板聚集（粘附和凝聚）、可溶性激动剂依赖性血小板活化和流经损伤的血流的常微分方程（ODE）系统组成。血小板聚集的形成会增加流经损伤处的阻力，这可以用斯托克斯-布林克曼方程来模拟。类似实验（微流体流动）和偏微分方程模型的数据为描述血小板粘附、凝聚和活化的 ODE 模型提供了参数值。该模型可预测一系列流动和血小板活化条件下的损伤闭塞情况。测试剪切力和活化率影响的模拟结果显示了延迟闭塞和聚集异质性。这些结果验证了我们的假设，即流动介导的活化化学物质二磷酸腺苷稀释会阻碍聚集体的形成。这种新颖的建模框架可以扩展到更多的血小板活化机制以及凝血的生化反应，从而成为一种计算高效的原发性和继发性止血高通量筛选工具。

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A MATHEMATICAL MODEL OF PLATELET AGGREGATION IN AN EXTRAVASCULAR INJURY UNDER FLOW.

We present the first mathematical model of flow-mediated primary hemostasis in an extravascular injury which can track the process from initial deposition to occlusion. The model consists of a system of ordinary differential equations (ODEs) that describe platelet aggregation (adhesion and cohesion), soluble-agonist-dependent platelet activation, and the flow of blood through the injury. The formation of platelet aggregates increases resistance to flow through the injury, which is modeled using the Stokes-Brinkman equations. Data from analogous experimental (microfluidic flow) and partial differential equation models informed parameter values used in the ODE model description of platelet adhesion, cohesion, and activation. This model predicts injury occlusion under a range of flow and platelet activation conditions. Simulations testing the effects of shear and activation rates resulted in delayed occlusion and aggregate heterogeneity. These results validate our hypothesis that flow-mediated dilution of activating chemical adenosine diphosphate hinders aggregate development. This novel modeling framework can be extended to include more mechanisms of platelet activation as well as the addition of the biochemical reactions of coagulation, resulting in a computationally efficient high throughput screening tool of primary and secondary hemostasis.

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来源期刊

Multiscale Modeling & Simulation 数学-数学跨学科应用

CiteScore

2.80

自引率

6.20%

发文量

审稿时长

6-12 weeks

期刊介绍： Centered around multiscale phenomena, Multiscale Modeling and Simulation (MMS) is an interdisciplinary journal focusing on the fundamental modeling and computational principles underlying various multiscale methods. By its nature, multiscale modeling is highly interdisciplinary, with developments occurring independently across fields. A broad range of scientific and engineering problems involve multiple scales. Traditional monoscale approaches have proven to be inadequate, even with the largest supercomputers, because of the range of scales and the prohibitively large number of variables involved. Thus, there is a growing need to develop systematic modeling and simulation approaches for multiscale problems. MMS will provide a single broad, authoritative source for results in this area.