The Influence of Material Properties and Wall Thickness on Predicted Wall Stress in Ascending Aortic Aneurysms: A Finite Element Study.

IF 1.6 4区 医学 Q3 CARDIAC & CARDIOVASCULAR SYSTEMS
Yu Zhu, Selene Pirola, M Yousuf Salmasi, Sumesh Sasidharan, Serena M Fisichella, Declan P O'Regan, James E Moore, Thanos Athanasiou, Xiao Yun Xu
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引用次数: 0

Abstract

Purpose: Finite element analysis (FEA) has been used to predict wall stress in ascending thoracic aortic aneurysm (ATAA) in order to evaluate risk of dissection or rupture. Patient-specific FEA requires detailed information on ATAA geometry, loading conditions, material properties, and wall thickness. Unfortunately, measuring aortic wall thickness and mechanical properties non-invasively poses a significant challenge, necessitating the use of non-patient-specific data in most FE simulations. This study aimed to assess the impact of employing non-patient-specific material properties and wall thickness on ATAA wall stress predictions.

Methods: FE simulations were performed on 13 ATAA geometries reconstructed from computed tomography angiography (CTA) images. Patient-specific material properties and wall thicknesses were made available from a previous study where uniaxial tensile testing was performed on tissue samples obtained from the same patients. The ATAA wall models were discretised with hexahedral elements and prestressed. For each ATAA model, FE simulations were conducted using patient-specific material properties and wall thicknesses, and group-mean values derived from all tissue samples included in the same experimental study. Literature-based material property and wall thickness were also obtained from the literature and applied to 4 representative cases. Additional FE simulations were performed on these 4 cases by employing group-mean and literature-based wall thicknesses.

Results: FE simulations using the group-mean material property produced peak wall stresses comparable to those obtained using patient-specific material properties, with a mean deviation of 7.8%. Peak wall stresses differed by 20.8% and 18.7% in patients with exceptionally stiff or compliant walls, respectively. Comparison to results using literature-based material properties revealed larger discrepancies, ranging from 5.4% to 28.0% (mean 20.1%). Bland-Altman analysis showed significant discrepancies in areas of high wall stress, where wall stress obtained using patient-specific and literature-based properties differed by up to 674 kPa, compared to 227 kPa between patient-specific and group-mean properties. Regarding wall thickness, using the literature-based value resulted in even larger discrepancies in predicted peak stress, ranging from 24.2% to 30.0% (mean 27.3%). Again, using the group-mean wall thickness offered better predictions with a difference less than 5% in three out of four cases. While peak wall stresses were most affected by the choice of mechanical properties or wall thickness, the overall distribution of wall stress hardly changed.

Conclusions: Our study demonstrated the importance of incorporating patient-specific material properties and wall thickness in FEA for risk prediction of aortic dissection or rupture. Our future efforts will focus on developing inverse methods for non-invasive determination of patient-specific wall material parameters and wall thickness.

材料特性和壁厚对升主动脉瘤预测壁应力的影响:有限元研究
目的:有限元分析(FEA)已被用于预测升胸主动脉瘤(ATAA)的壁应力,以评估夹层或破裂的风险。针对特定患者的有限元分析需要有关 ATAA 几何形状、加载条件、材料特性和壁厚的详细信息。遗憾的是,无创测量主动脉壁厚度和机械性能是一项重大挑战,因此大多数有限元模拟必须使用非患者特异性数据。本研究旨在评估采用非患者特异性材料特性和壁厚对 ATAA 壁应力预测的影响:方法:对根据计算机断层扫描血管造影(CTA)图像重建的 13 种 ATAA 几何形状进行了有限元模拟。患者特异性材料特性和壁厚可从之前的研究中获得,该研究对从相同患者身上获得的组织样本进行了单轴拉伸测试。ATAA 壁模型用六面体元素离散化并进行预应力处理。对于每个 ATAA 模型,均使用患者特定的材料属性和壁厚以及同一实验研究中所有组织样本得出的组均值进行有限元模拟。此外,还从文献中获取了基于文献的材料特性和壁厚,并将其应用于 4 个具有代表性的病例。通过使用组平均值和基于文献的壁厚,对这 4 个案例进行了额外的 FE 模拟:结果:使用组平均材料特性进行 FE 模拟得出的峰值壁应力与使用患者特定材料特性得出的峰值壁应力相当,平均偏差为 7.8%。壁特别僵硬或特别顺从的患者的峰值壁应力分别相差 20.8% 和 18.7%。与使用基于文献的材料特性得出的结果相比,差异更大,从5.4%到28.0%不等(平均20.1%)。Bland-Altman分析显示,在高壁应力区域存在显著差异,使用患者特异性材料和基于文献的材料特性得出的壁应力相差高达674千帕,而患者特异性材料和组平均值材料特性相差227千帕。关于壁厚,使用文献值导致预测峰值应力的差异更大,从 24.2% 到 30.0%(平均 27.3%)不等。同样,使用组平均壁厚的预测结果更好,四种情况中有三种的差异小于 5%。虽然峰值壁应力受机械性能或壁厚选择的影响最大,但壁应力的总体分布几乎没有变化:我们的研究表明,在有限元分析中纳入患者特异性材料特性和壁厚对于主动脉夹层或破裂的风险预测非常重要。我们今后的工作重点是开发无创确定患者特异性壁材料参数和壁厚的逆向方法。
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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来源期刊
Cardiovascular Engineering and Technology
Cardiovascular Engineering and Technology Engineering-Biomedical Engineering
CiteScore
4.00
自引率
0.00%
发文量
51
期刊介绍: Cardiovascular Engineering and Technology is a journal publishing the spectrum of basic to translational research in all aspects of cardiovascular physiology and medical treatment. It is the forum for academic and industrial investigators to disseminate research that utilizes engineering principles and methods to advance fundamental knowledge and technological solutions related to the cardiovascular system. Manuscripts spanning from subcellular to systems level topics are invited, including but not limited to implantable medical devices, hemodynamics and tissue biomechanics, functional imaging, surgical devices, electrophysiology, tissue engineering and regenerative medicine, diagnostic instruments, transport and delivery of biologics, and sensors. In addition to manuscripts describing the original publication of research, manuscripts reviewing developments in these topics or their state-of-art are also invited.
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