纤维蛋白纤维具有非凡的延展性和弹性。
Fibrin fibers have extraordinary extensibility and elasticity.
作者信息
Liu W, Jawerth L M, Sparks E A, Falvo M R, Hantgan R R, Superfine R, Lord S T, Guthold M
机构信息
Department of Physics, Wake Forest University, Winston-Salem, NC 27109, USA.
出版信息
Science. 2006 Aug 4;313(5787):634. doi: 10.1126/science.1127317.
Abstract
Blood clots perform an essential mechanical task, yet the mechanical behavior of fibrin fibers, which form the structural framework of a clot, is largely unknown. By using combined atomic force-fluorescence microscopy, we determined the elastic limit and extensibility of individual fibers. Fibrin fibers can be strained 180% (2.8-fold extension) without sustaining permanent lengthening, and they can be strained up to 525% (average 330%) before rupturing. This is the largest extensibility observed for protein fibers. The data imply that fibrin monomers must be able to undergo sizeable, reversible structural changes and that deformations in clots can be accommodated by individual fiber stretching.
摘要
血凝块执行着一项至关重要的机械任务,然而,构成血凝块结构框架的纤维蛋白纤维的机械行为却 largely unknown。通过联合使用原子力-荧光显微镜,我们确定了单个纤维的弹性极限和可拉伸性。纤维蛋白纤维能够被拉伸180%(2.8倍伸长)而不会持续永久伸长,并且在断裂前它们能够被拉伸高达525%(平均330%)。这是观察到的蛋白质纤维最大的可拉伸性。这些数据意味着纤维蛋白单体必须能够经历相当大的、可逆的结构变化,并且血凝块中的变形可以通过单个纤维的拉伸来适应。
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