用于模拟宏观、微观和多尺度血流的数值方法。

Numerical methods for simulating blood flow at macro, micro, and multi scales.

作者信息

Imai Yohsuke, Omori Toshihiro, Shimogonya Yuji, Yamaguchi Takami, Ishikawa Takuji

机构信息

School of Engineering, Tohoku University, Sendai, Japan.

出版信息

J Biomech. 2016 Jul 26;49(11):2221-2228. doi: 10.1016/j.jbiomech.2015.11.047. Epub 2015 Dec 4.

DOI:10.1016/j.jbiomech.2015.11.047

PMID:26705108

Abstract

In the past decade, numerical methods for the computational biomechanics of blood flow have progressed to overcome difficulties in diverse applications from cellular to organ scales. Such numerical methods may be classified by the type of computational mesh used for the fluid domain, into fixed mesh methods, moving mesh (boundary-fitted mesh) methods, and mesh-free methods. The type of computational mesh used is closely related to the characteristics of each method. We herein provide an overview of numerical methods recently used to simulate blood flow at macro and micro scales, with a focus on computational meshes. We also discuss recent progress in the multi-scale modeling of blood flow.

摘要

在过去十年中，用于血流计算生物力学的数值方法不断发展，以克服从细胞尺度到器官尺度等各种应用中的困难。此类数值方法可根据用于流体域的计算网格类型进行分类，分为固定网格方法、移动网格（边界拟合网格）方法和无网格方法。所使用的计算网格类型与每种方法的特性密切相关。在此，我们概述了最近用于模拟宏观和微观尺度血流的数值方法，重点关注计算网格。我们还讨论了血流多尺度建模的最新进展。

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用于模拟宏观、微观和多尺度血流的数值方法。

Numerical methods for simulating blood flow at macro, micro, and multi scales.

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