人工硬化红细胞的边缘化

Revaz D. Chachanidze, Othmane Aouane, Jens Harting, Christian Wagner, Marc Leonetti
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引用次数: 0

摘要

边缘化是白细胞从流动的血液迁移到血管壁的基本过程,这在生理学中已得到充分证实。然而,白细胞和红细胞在细胞大小和硬度上的差异是如何促成这一现象的仍是一个未决问题。为了研究细胞硬度的具体影响,我们对人工硬化红细胞二元混合物在健康细胞悬浮液中的分离进行了实验和数值研究。结果发现,硬化细胞在通道内的分布取决于通道的几何形状,狭缝、矩形和圆柱形横截面都证明了这一点。值得注意的是,在硬化红细胞的分布中出现了一个意想不到的中心峰值,同时在四角出现了四倍峰值,这与模拟结果一致。我们的研究结果揭示了分离/边缘化与血细胞比容和流速之间的非单调变化,这对普遍认为流速越高边缘化越强的观点提出了质疑。
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Margination of artificially stiffened red blood cells
Margination, a fundamental process in which leukocytes migrate from the flowing blood to the vessel wall, is well-documented in physiology. However, it is still an open question on how the differences in cell size and stiffness of white and red cells contribute to this phenomenon. To investigate the specific influence of cell stiffness, we conduct experimental and numerical studies on the segregation of a binary mixture of artificially stiffened red blood cells within a suspension of healthy cells. The resulting distribution of stiffened cells within the channel is found to depend on the channel geometry, as demonstrated with slit, rectangular, and cylindrical cross-sections. Notably, an unexpected central peak in the distribution of stiffened RBCs, accompanied by fourfold peaks at the corners, emerges in agreement with simulations. Our results unveil a non-monotonic variation in segregation/margination concerning hematocrit and flow rate, challenging the prevailing belief that higher flow rates lead to enhanced margination.
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