红细胞在血凝块收缩过程中的形态变化和多角体的结构。

Shape changes of erythrocytes during blood clot contraction and the structure of polyhedrocytes.

机构信息

Department of Cell and Developmental Biology, University of Pennsylvania School of Medicine, Philadelphia, PA, USA.

Institute of Fundamental Medicine and Biology, Kazan Federal University, Kazan, Russian Federation.

出版信息

Sci Rep. 2018 Dec 17;8(1):17907. doi: 10.1038/s41598-018-35849-8.

DOI:10.1038/s41598-018-35849-8

PMID:30559364

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6297136/

Abstract

Polyhedral erythrocytes, named polyhedrocytes, are formed in contracted blood clots and thrombi, as a result of compression by activated contractile platelets pulling on fibrin. This deformation was shown to be mechanical in nature and polyhedrocytes were characterized using light and electron microscopy. Through three-dimensional reconstruction, we quantified the geometry of biconcave, intermediate, and polyhedral erythrocytes within contracting blood clots. During compression, erythrocytes became less oblate and more prolate than the biconcave cells and largely corresponded to convex, irregular polyhedra with a total number of faces ranging from 10 to 16. Faces were polygons with 3 to 6 sides. The majority of the faces were quadrilaterals, though not all sides were straight and not all faces were flat. There were no changes in the surface area or volume. These results describe the gradual natural deformation of erythrocytes as a part of compaction into a tightly packed array that is an important but understudied component of mature blood clots and thrombi.

摘要

多面红细胞，又称多角形红细胞，在收缩的血凝块和血栓中形成，是由于激活的收缩血小板拉动纤维蛋白而产生的压缩。这种变形被证明是机械性质的，并且使用光和电子显微镜对多面红细胞进行了特征描述。通过三维重建，我们定量分析了收缩性血凝块中双凹面、中间和多面红细胞的几何形状。在压缩过程中，红细胞变得比双凹细胞更接近长形，而不是扁形，并且与凸面不规则多面体基本对应，其总面数从 10 到 16 不等。面是具有 3 到 6 个边的多边形。大多数面是四边形，尽管并非所有边都是直的，并非所有面都是平的。表面积和体积没有变化。这些结果描述了红细胞作为紧密堆积排列的一部分逐渐自然变形的过程，这是成熟血凝块和血栓的一个重要但研究不足的组成部分。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/c7ba/6297136/9371e9ab3d56/41598_2018_35849_Fig1_HTML.jpg

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红细胞在血凝块收缩过程中的形态变化和多角体的结构。

Shape changes of erythrocytes during blood clot contraction and the structure of polyhedrocytes.

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