二尖瓣的异质生物力学和力学生物学:对组织工程的启示。
The heterogeneous biomechanics and mechanobiology of the mitral valve: implications for tissue engineering.
机构信息
Department of Bioengineering, Rice University, Houston, TX 77005, USA.
出版信息
Curr Cardiol Rep. 2011 Apr;13(2):113-20. doi: 10.1007/s11886-010-0161-2.
Abstract
There are compelling reasons to develop a tissue-engineered mitral valve, but this endeavor has not received the same attention as tissue engineering strategies for the semilunar valves. Challenges in regenerating a mitral valve include recapitulating the complex heterogeneity in terms of anatomy (differently sized leaflets, numerous chordae), extracellular matrix composition, biomechanical behavior, valvular interstitial cell and endothelial cell phenotypes, and interior vasculature and innervation. It will also be essential to restore the functional relationships between the native mitral valve and left ventricle. A growing amount of information relevant to tissue engineering a mitral valve has been recently collected through investigations of cell mechanobiology and collagen organization. It is hoped that the development of tissue-engineered mitral valves can build on knowledge derived from engineering semilunar valves, but the mitral valve will present its own unique challenges as investigators move toward a first-generation prototype.
摘要
有充分的理由开发组织工程二尖瓣,但这项工作尚未像针对半月瓣的组织工程策略那样受到同样的关注。再生二尖瓣的挑战包括再现解剖结构(不同大小的瓣叶、众多的腱索)、细胞外基质组成、生物力学行为、瓣叶间质细胞和内皮细胞表型以及内部脉管系统和神经支配方面的复杂异质性。恢复原生二尖瓣与左心室之间的功能关系也将至关重要。通过对细胞机械生物学和胶原组织的研究,最近收集了大量与组织工程二尖瓣相关的信息。人们希望组织工程二尖瓣的发展可以建立在从工程半月瓣中获得的知识的基础上,但随着研究人员向第一代原型迈进,二尖瓣将带来其自身独特的挑战。
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