A High-Fidelity Computational Model for Predicting Blood Cell Trafficking and 3D Capillary Hemodynamics in Retinal Microvascular Networks.

IF 5 2区 医学 Q1 OPHTHALMOLOGY Investigative ophthalmology & visual science Pub Date : 2024-11-04 DOI:10.1167/iovs.65.13.37
Saman Ebrahimi, Phillip Bedggood, Yifu Ding, Andrew Metha, Prosenjit Bagchi
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Abstract

Purpose: To present a first principle-based, high-fidelity computational model for predicting full three-dimensional (3D) and time-resolved retinal microvascular hemodynamics taking into consideration the flow and deformation of individual blood cells.

Methods: The computational model is a 3D fluid-structure interaction model based on combined finite volume/finite element/immersed-boundary methods. Three in silico microvascular networks are built from high-resolution in vivo motion contrast images of the superficial capillary plexus in the parafoveal region of the human retina. The maximum tissue area represented in the model is approximately 500 × 500 µm2, and vessel lumen diameters ranged from 5.5 to 25 µm covering capillaries, arterioles, and venules. Blood is modeled as a suspension of individual blood cells, namely, erythrocytes (RBC), leukocytes (WBC), and platelets in plasma. An accurate and detailed biophysical modeling of each blood cell and their flow-induced deformation is considered. A physiological, pulsatile boundary condition corresponding to an average cardiac cycle of 0.9 second is used.

Results: Detailed quantitative data and analysis of 3D retinal microvascular hemodynamics are presented, and their relationship to RBC flow dynamics is illustrated. Blood velocity is shown to have temporal oscillations superimposed on the background pulsatile variation, which arise because of the way RBCs partition at vascular junctions, causing repeated clogging and unclogging of vessels. Temporal variations in RBC velocity and hematocrit are anti-correlated in a given vessel, but their time-averaged distributions are positively correlated across the network. Whole blood velocity is 65% to 85% of RBC velocity, with the discrepancy related to the formation of an RBC-free region, adjacent to the vascular endothelium and typically 0.8 to 1.8 µm thick. The 3D velocity and RBC concentration profiles are shown to be oppositely skewed with respect to each other, because of the way that RBCs "hug" the apex of each bifurcation. RBC deformation is predicted to have biphasic behavior with respect to vessel diameter, with minimal cell length for vessels approximately 7 µm in diameter. The wall shear stress (WSS) exhibits a strongly 3D distribution with local regions of high value and gradient spanning a range of 10 to 80 dyn/cm2. WSS is highest where there is faster flow, greater curvature of the vessel wall, capillary bifurcations, and at locations of RBC crowding and associated thinning of the cell-free layer.

Conclusions: This study highlights the usefulness of high-fidelity cell-resolved modeling to obtain accurate and detailed 3D, time-resolved retinal hemodynamic parameters that are not readily available through noninvasive imaging approaches. The results presented are expected to complement and enhance the interpretation of in vivo data, as well as open new avenues to study retinal hemodynamics in health and disease.

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预测视网膜微血管网络中血细胞流动和三维毛细血管血流动力学的高保真计算模型。
目的:首次提出一种基于原理的高保真计算模型,用于预测全三维和时间分辨视网膜微血管血流动力学,同时考虑到单个血细胞的流动和变形:计算模型是基于有限体积/有限元/浸润边界法的三维流固耦合模型。根据人类视网膜视网膜旁区域浅表毛细血管丛的高分辨率活体运动对比图像,建立了三个硅学微血管网络。模型中代表的最大组织面积约为 500 × 500 µm2,血管腔直径从 5.5 到 25 µm 不等,涵盖毛细血管、动脉和静脉。血液被模拟为悬浮在血浆中的单个血细胞,即红细胞(RBC)、白细胞(WBC)和血小板。对每个血细胞及其流动引起的变形进行了精确而详细的生物物理建模。使用了与平均 0.9 秒心脏周期相对应的生理脉动边界条件:结果:展示了三维视网膜微血管血液动力学的详细定量数据和分析,并说明了它们与红细胞流动动力学的关系。结果表明,血流速度具有叠加在背景脉动变化之上的时间振荡,这是因为 RBC 在血管连接处的分流方式导致血管反复堵塞和疏通。在特定血管中,红细胞速度和血细胞比容的时间变化是反相关的,但它们在整个网络中的时间平均分布却是正相关的。全血速度是 RBC 速度的 65% 至 85%,这一差异与无 RBC 区域的形成有关,该区域紧邻血管内皮,厚度通常为 0.8 至 1.8 µm。由于 RBC 会 "拥抱 "每个分叉的顶点,因此三维速度曲线和 RBC 浓度曲线显示出相互反向倾斜。根据预测,红细胞变形与血管直径呈双相行为,直径约为 7 µm 的血管细胞长度最小。血管壁剪切应力(WSS)呈现强烈的三维分布,局部区域数值较高,梯度范围为 10 至 80 达因/平方厘米。在流速较快、血管壁曲率较大、毛细血管分叉处以及 RBC 拥挤和无细胞层变薄的位置,WSS 值最高:这项研究强调了高保真细胞分辨建模在获得准确、详细的三维、时间分辨视网膜血流动力学参数方面的作用,而这些参数无法通过无创成像方法轻易获得。研究结果有望补充和加强对体内数据的解读,并为研究健康和疾病中的视网膜血流动力学开辟新的途径。
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来源期刊
CiteScore
6.90
自引率
4.50%
发文量
339
审稿时长
1 months
期刊介绍: Investigative Ophthalmology & Visual Science (IOVS), published as ready online, is a peer-reviewed academic journal of the Association for Research in Vision and Ophthalmology (ARVO). IOVS features original research, mostly pertaining to clinical and laboratory ophthalmology and vision research in general.
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