血凝块的破裂力学:纤维蛋白网络结构对破裂阻力的影响

IF 9.4 1区 医学 Q1 ENGINEERING, BIOMEDICAL
Ranjini K. Ramanujam , Farkhad Maksudov , Rebecca A. Risman , Rustem I. Litvinov , John W. Weisel , John L. Bassani , Valeri Barsegov , Prashant K. Purohit , Valerie Tutwiler
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引用次数: 0

摘要

栓塞是导致死亡的一个主要原因,但我们对血凝块的破裂机理知之甚少。纤维蛋白为血凝块提供了主要的结构和机械稳定性。以往的研究表明,改变凝血活化剂(凝血酶或组织因子(TF))的浓度对纤维蛋白的结构和粘弹性能有重大影响,但它们对破裂性能的影响大多尚不清楚。韧性相当于抵抗破裂的能力,与粘弹性无关。我们使用不同浓度的 TF 来改变人血浆凝块的结构和韧性。我们进行了单边缺口破裂试验,以检验纤维蛋白在恒定应变速率下的韧性,并使用流变学方法评估粘弹性力学。我们利用荧光共聚焦显微镜和扫描电子显微镜(SEM)量化了不同 TF 浓度下的纤维蛋白网络结构。我们的研究结果表明,增加 TF 浓度会导致纤维蛋白纤维数量增加,但网络孔径减小,纤维蛋白纤维变细变短。因此,纤维蛋白直径和纤维数量在影响血凝块的抗破裂性方面起着复杂的作用,导致 TF 和韧性之间的非单调关系。我们在波动弹簧(FS)计算模型的基础上建立了一个简单的机械模型,用于估算断裂韧性(临界能量释放率)与 TF 的函数关系,其预测趋势与实验结果非常吻合。机械响应的差异表明,研究纤维蛋白网络的结构-功能关系非常重要,这可能预示着栓塞的趋势。意义说明:纤维蛋白是一种天然生物材料,是血凝块的主要机械和结构支架,可为血凝块提供必要的强度和稳定性,确保有效止血。血凝块破裂会导致下游血管堵塞,从而阻断血流和氧气供应。纤维蛋白网络结构已被证明会影响血凝块的粘弹性力学性能,但在断裂力学方面还未进行过探索。在此,我们通过改变组织因子(TF)的浓度来调节纤维蛋白网络结构。有趣的是,TF 浓度与凝块最大韧性之间的关系是非单调的。机械反应的变化凸显了研究纤维蛋白网络结构-功能关系的重要性,因为这些关系可能预示着栓塞的倾向。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Rupture mechanics of blood clots: Influence of fibrin network structure on the rupture resistance

Rupture mechanics of blood clots: Influence of fibrin network structure on the rupture resistance
Embolization is a leading cause of mortality, yet we know little about clot rupture mechanics. Fibrin provides the main structural and mechanical stability to blood clots. Previous studies have shown that altering the concentration of coagulation activators (thrombin or tissue factor (TF)) has a significant impact on fibrin structure and viscoelastic properties, but their effects on rupture properties are mostly unknown. Toughness, which corresponds to the ability to resist rupture, is independent of viscoelastic properties. We used varying TF concentrations to alter the structure and toughness of human plasma clots. We performed single-edge notch rupture tests to examine fibrin toughness under a constant strain rate and we assessed viscoelastic mechanics using rheology. We utilized fluorescent confocal and scanning electron microscopy (SEM) to quantify the fibrin network structure under varying TF concentrations. Our results revealed that increased TF concentration resulted in increased number of fibrin fibers with a reduction in network pore size, thinner and shorter fibrin fibers. Increasing TF concentration yielded a maximum toughness at mid-TF concentration, such that fibrin diameter and number of fibers underlie a complex role in influencing the rupture resistance of blood clots, resulting in a nonmonotonic relationship between TF and toughness. A simple mechanical model, built on our findings from our Fluctuating Spring (FS) computational model, adopted to estimate the fracture toughness (critical energy release rate) as a function of TF predicts trends that are in good agreement with experiments. The differences in mechanical responses point to the importance of studying the structure-function relationships of fibrin networks, which may be predictive of the tendency for embolization.

Statement of significance

Fibrin, a naturally occurring biomaterial, is the main mechanical and structural scaffold of blood clots that provides the necessary strength and stability to the clot, ensuring effective stemming of bleeding. The rupture of blood clots can result in the blockage of downstream vessels thereby blocking blood flow and oxygen supply. The fibrin network structure has been shown to influence the viscoelastic mechanical properties of clots, but has not been explored for fracture mechanics. Here, we modulate the fibrin network structure by varying the concentration of Tissue Factor (TF). Interestingly, the association between TF concentration and maximum toughness of the clots is non-monotonic. The variations in mechanical responses highlight the importance of studying the structure-function relationships of fibrin networks, as these may predict the tendency for embolization.
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来源期刊
Acta Biomaterialia
Acta Biomaterialia 工程技术-材料科学:生物材料
CiteScore
16.80
自引率
3.10%
发文量
776
审稿时长
30 days
期刊介绍: Acta Biomaterialia is a monthly peer-reviewed scientific journal published by Elsevier. The journal was established in January 2005. The editor-in-chief is W.R. Wagner (University of Pittsburgh). The journal covers research in biomaterials science, including the interrelationship of biomaterial structure and function from macroscale to nanoscale. Topical coverage includes biomedical and biocompatible materials.
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