Angiogenic Microvascular Wall Shear Stress Patterns Revealed Through Three-dimensional Red Blood Cell Resolved Modeling.

IF 5.1 Q2 CELL BIOLOGY
Function (Oxford, England) Pub Date : 2023-08-29 eCollection Date: 2023-01-01 DOI:10.1093/function/zqad046
Mir Md Nasim Hossain, Nien-Wen Hu, Maram Abdelhamid, Simerpreet Singh, Walter L Murfee, Peter Balogh
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引用次数: 0

Abstract

The wall shear stress (WSS) exerted by blood flowing through microvascular capillaries is an established driver of new blood vessel growth, or angiogenesis. Such adaptations are central to many physiological processes in both health and disease, yet three-dimensional (3D) WSS characteristics in real angiogenic microvascular networks are largely unknown. This marks a major knowledge gap because angiogenesis, naturally, is a 3D process. To advance current understanding, we model 3D red blood cells (RBCs) flowing through rat angiogenic microvascular networks using state-of-the-art simulation. The high-resolution fluid dynamics reveal 3D WSS patterns occurring at sub-endothelial cell (EC) scales that derive from distinct angiogenic morphologies, including microvascular loops and vessel tortuosity. We identify the existence of WSS hot and cold spots caused by angiogenic surface shapes and RBCs, and notably enhancement of low WSS regions by RBCs. Spatiotemporal characteristics further reveal how fluctuations follow timescales of RBC "footprints." Altogether, this work provides a new conceptual framework for understanding how shear stress might regulate EC dynamics in vivo.

通过三维红细胞解析模型揭示的血管生成微血管壁剪切应力模式。
流经微血管毛细血管的血液所施加的壁剪切应力(WSS)是新血管生长或血管生成的既定驱动因素。这种适应是健康和疾病中许多生理过程的核心,然而真实血管生成微血管网络中的三维(3D)WSS特征在很大程度上是未知的。这标志着一个重大的知识差距,因为血管生成自然是一个3D过程。为了推进目前的理解,我们使用最先进的模拟对流经大鼠血管生成微血管网络的3D红细胞(RBCs)进行了建模。高分辨率流体动力学揭示了在内皮下细胞(EC)尺度上发生的3D WSS模式,这些模式源于不同的血管生成形态,包括微血管环和血管扭曲。我们确定了由血管生成表面形状和RBCs引起的WSS热点和冷点的存在,并且RBCs显著增强了低WSS区域。时空特征进一步揭示了波动如何遵循RBC“足迹”的时间尺度。总之,这项工作为理解剪切应力如何在体内调节EC动力学提供了一个新的概念框架。
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
CiteScore
5.70
自引率
0.00%
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0
审稿时长
3 weeks
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