Valve interstitial cells under impact load, a mechanobiology study.

Dylan Goode, Ruby Dhaliwal, Hadi Mohammadi
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Abstract

Understanding the relationship between mechanobiology and the biosynthetic activities of the valve interstitial cells (VICs) in health and disease under severe dynamic loading conditions is of particular interest. The purpose of this study is to further understand the mechanobiology of heart valve leaflet tissue and the VICs under impact forces. Two novel computational and experimental platforms were developed to study the effect of impact load on the VICs to monitor for apoptosis. The first objective was to design and develop an apparatus to experimentally study viability (apoptosis) of the porcine heart valve leaflet tissue VICs in the aortic position under controlled impact forces. Apoptosis was assessed based on terminal transferase dUTP nick end-labelling (TUNEL) assay. The second objective was to develop a computational platform to estimate the stress and strain fields in the vicinity of VICs when the tissue experiences impact forces. A nonlinear finite element (FE) model with an anisotropic, hyperelastic and heterogeneous material model for the matrix and cells was developed. Preliminary results confirm that interstitial cells are successfully resistant to impact loads up to 30 times more than normal physiological conditions. Additionally, the structure and composition of heart valve leaflet tissue provides a mechanical shield for VICs protecting them from excessive mechanical forces such as impact loads. Although, the entire tissue may experience excessive stresses, which may lead to structural damage, the stresses around and near VICs remain consistency low. Results of this study may be used for heart valve leaflet tissue-engineering, as well as further understanding the mechanobiology of the VICs in health and disease.

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冲击载荷下瓣膜间质细胞的力学生物学研究。
了解机械生物学和瓣膜间质细胞(vic)在健康和疾病中在严重动态负荷条件下的生物合成活性之间的关系是特别感兴趣的。本研究旨在进一步了解冲击作用下心脏瓣膜小叶组织及vic的力学生物学。建立了两个新的计算和实验平台来研究冲击载荷对vic的影响,以监测细胞凋亡。第一个目的是设计和开发一种装置,实验研究在可控冲击力下猪主动脉位置瓣膜小叶组织vic的生存能力(细胞凋亡)。通过末端转移酶dUTP缺口末端标记(TUNEL)法评估细胞凋亡。第二个目标是开发一个计算平台,以估计组织受到冲击力时vic附近的应力和应变场。建立了具有各向异性、超弹性和非均质材料模型的非线性有限元模型。初步结果证实,间质细胞能够成功抵抗比正常生理条件下高30倍的冲击载荷。此外,心脏瓣膜小叶组织的结构和组成为vic提供了一个机械屏蔽,保护他们免受过大的机械力,如冲击载荷。尽管整个组织可能承受过大的应力,这可能导致结构损伤,但vic周围和附近的应力始终保持较低。本研究结果可用于心脏瓣膜小叶的组织工程,以及进一步了解心脏瓣膜在健康和疾病中的机制生物学。
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来源期刊
Journal of Medical Engineering and Technology
Journal of Medical Engineering and Technology Engineering-Biomedical Engineering
CiteScore
4.60
自引率
0.00%
发文量
77
期刊介绍: The Journal of Medical Engineering & Technology is an international, independent, multidisciplinary, bimonthly journal promoting an understanding of the physiological processes underlying disease processes and the appropriate application of technology. Features include authoritative review papers, the reporting of original research, and evaluation reports on new and existing techniques and devices. Each issue of the journal contains a comprehensive information service which provides news relevant to the world of medical technology, details of new products, book reviews, and selected contents of related journals.
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