二维全血模拟中血小板在血管壁或血栓表面附近的运动。
Platelet motion near a vessel wall or thrombus surface in two-dimensional whole blood simulations.
机构信息
Department of Mathematics, University of Utah, Salt Lake City, Utah, USA.
出版信息
Biophys J. 2013 Apr 16;104(8):1764-72. doi: 10.1016/j.bpj.2013.01.061.
Abstract
Computational simulations using a two-dimensional lattice-Boltzmann immersed boundary method were conducted to investigate the motion of platelets near a vessel wall and close to an intravascular thrombus. Physiological volume fractions of deformable red blood cells and rigid platelet-size elliptic particles were studied under arteriolar flow conditions. Tumbling of platelets in the red-blood-cell depleted zone near the vessel walls was strongly influenced by nearby red blood cells. The thickness of the red-blood-cell depleted zone was greatly reduced near a thrombus, and platelets in this zone were pushed close to the surface of the thrombus to distances that would facilitate their cohesion to it. The distance, nature, and duration of close platelet-thrombus encounters were influenced by the porosity of the thrombus. The strong influence on platelet-thrombus encounters of red-blood-cell motion and thrombus porosity must be taken into account to understand the dynamics of platelet attachment to a growing thrombus.
摘要
使用二维格子玻尔兹曼浸入边界法进行计算模拟,研究了血小板在血管壁附近和靠近血管内血栓时的运动。在动脉流动条件下,研究了可变形红细胞和刚性血小板大小椭圆形颗粒的生理体积分数。在血管壁附近的红细胞耗竭区,血小板的翻滚受到附近红细胞的强烈影响。在血栓附近,红细胞耗竭区的厚度大大减小,并且该区域中的血小板被推到靠近血栓表面的距离,这有利于它们与之凝聚。血小板-血栓近距离接触的距离、性质和持续时间受血栓的孔隙率影响。必须考虑红细胞运动和血栓孔隙率对血小板-血栓接触的强烈影响,以了解血小板附着在生长中的血栓上的动力学。
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