Dynamic deformability of sickle red blood cells in microphysiological flow.

Y Alapan, Y Matsuyama, J A Little, U A Gurkan
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引用次数: 54

Abstract

In sickle cell disease (SCD), hemoglobin molecules polymerize intracellularly and lead to a cascade of events resulting in decreased deformability and increased adhesion of red blood cells (RBCs). Decreased deformability and increased adhesion of sickle RBCs lead to blood vessel occlusion (vaso-occlusion) in SCD patients. Here, we present a microfluidic approach integrated with a cell dimensioning algorithm to analyze dynamic deformability of adhered RBC at the single-cell level in controlled microphysiological flow. We measured and compared dynamic deformability and adhesion of healthy hemoglobin A (HbA) and homozygous sickle hemoglobin (HbS) containing RBCs in blood samples obtained from 24 subjects. We introduce a new parameter to assess deformability of RBCs: the dynamic deformability index (DDI), which is defined as the time-dependent change of the cell's aspect ratio in response to fluid flow shear stress. Our results show that DDI of HbS-containing RBCs were significantly lower compared to that of HbA-containing RBCs. Moreover, we observed subpopulations of HbS containing RBCs in terms of their dynamic deformability characteristics: deformable and non-deformable RBCs. Then, we tested blood samples from SCD patients and analyzed RBC adhesion and deformability at physiological and above physiological flow shear stresses. We observed significantly greater number of adhered non-deformable sickle RBCs than deformable sickle RBCs at flow shear stresses well above the physiological range, suggesting an interplay between dynamic deformability and increased adhesion of RBCs in vaso-occlusive events.

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微生理流动中镰状红细胞的动态变形能力。
在镰状细胞病(SCD)中,血红蛋白分子在细胞内聚合并导致一系列事件,导致红细胞(rbc)的可变形性降低和粘连性增加。镰状红细胞的变形性降低和粘连性增加导致SCD患者血管闭塞(血管闭塞)。在这里,我们提出了一种结合细胞量纲算法的微流体方法来分析在受控微生理流动中粘附红细胞在单细胞水平上的动态变形能力。我们测量并比较了24名受试者血液样本中健康血红蛋白A (HbA)和含红细胞的纯合镰状血红蛋白(HbS)的动态变形能力和粘附性。我们引入了一个新的参数来评估红细胞的变形能力:动态变形指数(DDI),它被定义为细胞的纵横比响应于流体流动剪切应力的随时间变化。我们的研究结果表明,含hba的红细胞的DDI明显低于含hba的红细胞。此外,我们还观察了含有红细胞的HbS亚群的动态变形特性:可变形红细胞和不可变形红细胞。然后,我们测试了SCD患者的血液样本,并分析了生理和高于生理流动剪切应力下红细胞的粘附性和变形性。我们观察到,在远高于生理范围的血流剪切应力下,黏附的不可变形镰状红细胞数量明显多于可变形镰状红细胞,这表明在血管闭塞事件中,红细胞的动态可变形性和黏附性增加之间存在相互作用。
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TECHNOLOGY
TECHNOLOGY ENGINEERING, MULTIDISCIPLINARY-
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