Ultimate tensile strength and biaxial stress–strain responses of aortic tissues—A clinical-engineering correlation

IF 2.2 Q2 ENGINEERING, MULTIDISCIPLINARY Applications in engineering science Pub Date : 2022-06-01 DOI:10.1016/j.apples.2022.100101
Hai Dong , Minliang Liu , Xiaoying Lou , Bradley G. Leshnower , Wei Sun , Bulat A. Ziganshin , Mohammad A. Zafar , John A. Elefteriades
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Abstract

For over a decade, the team from the Aortic Institute at Yale University has worked closely with the bioengineering team of Dr. Wei Sun at Georgia Tech University. This paper presents the products of that collaboration.

We provide clinical context by describing thoracic aortic dissection and its genesis as a prelude to the bioengineering findings. We discuss the genesis of aortic dissection, from the fundamental underlying genetic abnormality, through the degenerative aortic process, to the acute inciting factors and the dissection event itself. The inciting factor is usually an extreme hypertensive episode, occasioned by exertion or emotion.

The bioengineering findings include the following: The aortic wall is stronger in the circumferential direction than in the longitudinal. Bicuspid aortic valve and bovine aortic arch morphology do not compromise aortic strength. Biaxial testing reveals a non-liner stress-strain response of aortic tissues. Dissected tissues become stronger over time, reflecting fibrotic connective tissue ingrowth in response to the dramatic tissue injury from the dissection event. Human aortic tissues stiffen at advanced age, in contradistinction to those of aged animals (porcine).

Combining clinical and bioengineering perspectives yields a more complete and correlative understanding of the genesis of thoracic aortic dissection.

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主动脉组织的极限拉伸强度和双轴应力-应变响应-临床工程相关性
十多年来,耶鲁大学主动脉研究所的研究小组一直与佐治亚理工大学孙伟博士的生物工程团队密切合作。本文介绍了这种合作的成果。我们通过描述胸主动脉夹层及其起源作为生物工程发现的前奏来提供临床背景。我们讨论了主动脉夹层的起源,从基本的潜在遗传异常,通过主动脉退行性过程,到急性刺激因素和夹层事件本身。刺激因素通常是由劳累或情绪引起的极端高血压发作。生物工程结果包括:主动脉壁在周向比纵向更强。二尖瓣主动脉瓣和牛主动脉弓形态不影响主动脉强度。双轴测试显示主动脉组织的非线性应力应变响应。随着时间的推移,剥离的组织变得更强,这反映了纤维化结缔组织在剥离事件造成的严重组织损伤下向内生长的反应。与年老动物(猪)不同,人的主动脉组织在年老时变硬。结合临床和生物工程的观点,对胸主动脉夹层的发生有了更完整和相关的认识。
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来源期刊
Applications in engineering science
Applications in engineering science Mechanical Engineering
CiteScore
3.60
自引率
0.00%
发文量
0
审稿时长
68 days
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