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红细胞增强血小板在突然扩张处浓度的微流可视化。

Micro-flow visualization of red blood cell-enhanced platelet concentration at sudden expansion.

作者信息

Zhao Rui, Marhefka Joie N, Shu Fangjun, Hund Samuel J, Kameneva Marina V, Antaki James F

机构信息

Department of Biomedical Engineering, Carnegie Mellon University, Pittsburgh, PA, USA.

出版信息

Ann Biomed Eng. 2008 Jul;36(7):1130-41. doi: 10.1007/s10439-008-9494-z. Epub 2008 Apr 17.

DOI:10.1007/s10439-008-9494-z
PMID:18418710
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6390961/
Abstract

Microscopic steps and crevices are inevitable features within prosthetic blood-contacting devices. This study aimed to elucidate the thrombogenicity of the associated microscopic flow features by studying the transport of fluorescent platelet-sized particles in a suspension of red blood cells (RBCs) flowing through a 100 microm:200 microm sudden expansion. Micro-flow visualization revealed a strong influence of hematocrit upon the path of RBCs and spatial concentration of particles. At all flow rates studied (Re = 8.3-41.7) and hematocrit 20% and lower, RBC streamlines were found to detach from the microchannel wall creating an RBC-depleted zone inside the step that was much larger than the cells themselves. However, the observed distribution of particles was relatively homogeneous. By contrast, the RBC streamlines of samples with hematocrit equal to or greater than 30% more closely followed the contour of the microchannel, yet exhibited enhanced concentration of particles within the corner. The corresponding size of the cell depletion layer was comparable with the size of the cells. This study implies that local platelet concentration in blood within the physiological range of hematocrit can be elevated within the flow separation region of a sudden expansion and implicates the role of RBCs in causing this effect.

摘要

微观台阶和缝隙是人工血液接触装置中不可避免的特征。本研究旨在通过研究荧光血小板大小颗粒在流经100微米×200微米突然扩张段的红细胞(RBC)悬浮液中的输运情况,阐明相关微观流动特征的血栓形成性。微观流动可视化显示血细胞比容对红细胞路径和颗粒空间浓度有强烈影响。在所研究的所有流速(雷诺数Re = 8.3 - 41.7)以及血细胞比容为20%及更低时,发现红细胞流线从微通道壁分离,在台阶内部形成一个比细胞本身大得多的红细胞耗尽区。然而,观察到的颗粒分布相对均匀。相比之下,血细胞比容等于或大于30%的样品的红细胞流线更紧密地跟随微通道轮廓,但在拐角处颗粒浓度增加。相应的细胞耗尽层大小与细胞大小相当。本研究表明,在血细胞比容的生理范围内,血液中的局部血小板浓度在突然扩张的流动分离区域内会升高,并暗示了红细胞在造成这种效应中的作用。

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