猪肾动脉的生物力学及轴向拉伸的作用。
Biomechanics of porcine renal arteries and role of axial stretch.
作者信息
Avril Stéphane, Badel Pierre, Gabr Mohamed, Sutton Michael A, Lessner Susan M
机构信息
Ecole Nationale Supe´rieure des Mines CIS-ENSMSE, CNRS:UMR5146 Saint-Etienne F-42023, France.
出版信息
J Biomech Eng. 2013 Aug;135(8):81007. doi: 10.1115/1.4024685.
Abstract
It is known that arteries experience significant axial stretches in vivo. Several authors have shown that the axial force needed to maintain an artery at its in vivo axial stretch does not change with transient cyclical pressurization over normal ranges. However, the axial force phenomenon of arteries has never been explained with microstructural considerations. In this paper we propose a simple biomechanical model to relate the specific axial force phenomenon of arteries to the predicted load-dependent average collagen fiber orientation. It is shown that (a) the model correctly predicts the authors' experimentally measured biaxial behavior of pig renal arteries and (b) the model predictions are in agreement with additional experimental results reported in the literature. Finally, we discuss the implications of the model for collagen fiber orientation and deposition in arteries.
摘要
众所周知,动脉在体内会经历显著的轴向拉伸。几位作者已经表明,在正常范围内,将动脉维持在其体内轴向拉伸所需的轴向力不会随瞬态周期性加压而改变。然而,动脉的轴向力现象从未从微观结构角度得到解释。在本文中,我们提出了一个简单的生物力学模型,将动脉的特定轴向力现象与预测的依赖负荷的平均胶原纤维取向联系起来。结果表明:(a)该模型正确地预测了作者实验测量的猪肾动脉双轴行为;(b)模型预测与文献中报道的其他实验结果一致。最后,我们讨论了该模型对动脉中胶原纤维取向和沉积的影响。
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