应变硬化对人体动脉段动态响应的影响。

Q3 Medicine Open Biomedical Engineering Journal Pub Date : 2017-09-26 eCollection Date: 2017-01-01 DOI:10.2174/1874120701711010085
Haralambia P Charalambous, Panayiotis C Roussis, Antonios E Giannakopoulos
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引用次数: 6

摘要

背景:当血压随时间变化时,人体动脉发生大变形,主要表现为非线性超弹性型反应。动脉的机械反应取决于构成动脉壁的组织的健康状况。通常,健康动脉在拉伸载荷下表现为凸应变硬化,动脉粥样硬化部位表现为硬化反应,而动脉瘤部位表现为软化反应。实际上,动脉动力学是脉冲传播的动力学,起源于心脏心室,沿着主动脉传播,分叉等。动脉作为一个整体不能被模拟成一个块状环,但是它的横截面可以被模拟成一个相对于其他部分有相位滞后的振动环,从而产生一个运行的压力波。一个完整的数学模型将需要流体-固体相互作用模型,模拟柔顺血管中血流的连续性和动量方程。另一方面,实验室测试通常使用小长度动脉,其响应在本工作中被覆盖。通过这种方式,可以研究沿动脉长度变化的材料特性。目的:通过适当的与血管健康状况相关的超弹性模型,研究应变硬化对人体动脉局部动力响应(不包括完全的流固相互作用)的影响。此外,这项工作旨在为进一步研究动脉的动态响应奠定基础。方法:基于Skalak等人、Hariton和Mooney-Rivlin提出的本构律,分别与健康动脉、动脉粥样硬化动脉和动脉瘤动脉的硬化行为相关,为三种不同的超弹性材料行为制定了运动控制方程。这些建模实现之间的差异是由生理学引起的,因为动脉瘤动脉较软,而硬化动脉通常比健康动脉更硬。响应是通过适当的归一化所涉及的材料参数的动脉壁,动脉的几何形状,载荷历史,时间效应和预应力的研究。研究了各问题参数对动脉反应的影响。动脉段的峰值响应是根据径向位移、主伸长、主应力和应变能密度来计算的。通过与先前研究动脉模型动态响应的研究进行比较,证明了所提出的分析模型的有效性。结果:径向变形和最大应变能密度随径向共振频率变化是血管外科手术的重要指标。这些指标受模型的非线性应变硬化特性和纵向预应力的影响很大。结论:所提出的公式允许进行系统和可推广的调查,加上分析的计算成本低,使其成为计算健康、动脉粥样硬化和动脉瘤动脉反应的有价值的工具。径向共振频率可以解释狭窄动脉中出现的某些杂音。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

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The Effect of Strain Hardening on the Dynamic Response of Human Artery Segments.

Background: When subjected to time-dependent blood pressure, human arteries undergo large deformations, exhibiting mainly nonlinear hyperelastic type of response. The mechanical response of arteries depends on the health of tissues that comprise the artery walls. Typically, healthy arteries exhibit convex strain hardening under tensile loads, atherosclerotic parts exhibit stiffer response, and aneurysmatic parts exhibit softening response. In reality, arterial dynamics is the dynamics of a propagating pulse, originating in heart ventricle, propagating along aorta, bifurcating, etc. Artery as a whole cannot be simulated as a lump ring, however its cross section can be simulated as a vibrating ring having a phase lag with respect to the other sections, creating a running pressure wave. A full mathematical model would require fluid-solid interaction modeling continuity of blood flow in a compliant vessel and a momentum equation. On the other hand, laboratory testing often uses small-length arteries, the response of which is covered by the present work. In this way, material properties that change along the artery length can be investigated.

Objective: The effect of strain hardening on the local dynamic response of human arteries (excluding the full fluid-structure interaction) is examined through appropriate hyperelastic models related to the health condition of the blood vessel. Furthermore, this work aims at constituting a basis for further investigation of the dynamic response of arteries accounting for viscosity.

Method: The governing equation of motion is formulated for three different hyperelastic material behaviors, based on the constitutive law proposed by Skalak et al., Hariton, and Mooney-Rivlin, associated with the hardening behavior of healthy, atherosclerotic, and aneurysmatic arteries, respectively. The differences between these modelling implementations are caused by physiology, since aneurysmatic arteries are softer and often sclerotic arteries are stiffer than healthy arteries. The response is investigated by proper normalization of the involved material parameters of the arterial walls, geometry of the arteries, load histories, time effects, and pre-stressing. The effect of each problem parameter on the arterial response has been studied. The peak response of the artery segment is calculated in terms of radial displacements, principal elongations, principal stresses, and strain-energy density. The validity of the proposed analytical models is demonstrated through comparison with previous studies that investigate the dynamic response of arterial models.

Results: Important metrics that can be useful to vascular surgery are the radial deformation and the maximum strain-energy density along with the radial resonance frequencies. These metrics are found to be influenced heavily by the nonlinear strain-hardening characteristics of the model and the longitudinal pre-stressing.

Conclusion: The proposed formulation permits a systematic and generalizable investigation, which, together with the low computational cost of analysis, makes it a valuable tool for calculating the response of healthy, atherosclerotic, and aneurysmatic arteries. The radial resonance frequencies can explain certain murmures developed in stenotic arteries.

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来源期刊
Open Biomedical Engineering Journal
Open Biomedical Engineering Journal Medicine-Medicine (miscellaneous)
CiteScore
1.60
自引率
0.00%
发文量
4
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