Development and characterization of improved tissue engineered valve-equivalents using chemical and mechanical signaling

中国地球物理学会年刊 Pub Date : 2002-12-01 DOI:10.1109/IEMBS.2002.1137112

M. Neidert, J. Wille, R. Tranquillo

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引用次数: 2

Abstract

Tissue engineered valves hold considerable promise as replacement valves that avoid many of the problems present in current replacement valve technology. Furthermore, these valves, as a living construct, would be able to grow and remodel in vivo. We have developed a bileaflet biopolymer-scaffold based valve equivalent that possesses the correct geometry and underlying collagen fibril alignment. These valve-equivalents, however, have significantly worse mechanical properties as compared to healthy, native valves (in terms of ultimate tensile stress and tangent modulus). Furthermore, valve equivalents with initial collagen scaffolds show very little compositional remodeling leaving a predominantly collagen valve with little of the elastin and proteoglycan content present in native valves. We present work here aimed at improving the compositional and mechanical properties of valve-equivalents (VEs) by using a combination of chemical signaling by using a fibrin (as opposed to collagen) scaffold incubated with TGF-/spl beta/ and insulin and mechanical signaling achieved by VE incubation in a bioreactor.

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利用化学和机械信号技术开发和表征改良的组织工程等效阀

组织工程瓣膜作为替代瓣膜具有相当大的前景，可以避免当前替代瓣膜技术中存在的许多问题。此外，这些瓣膜作为一个活体结构，能够在体内生长和重塑。我们已经开发出一种基于双支架生物聚合物支架的瓣膜等效物，它具有正确的几何形状和潜在的胶原纤维排列。然而，与健康的天然阀门相比，这些阀门的机械性能明显较差(就极限拉伸应力和切线模量而言)。此外，与初始胶原支架相当的瓣膜显示很少的成分重塑，留下以胶原为主的瓣膜，很少有天然瓣膜中存在的弹性蛋白和蛋白聚糖含量。我们在此提出的工作旨在通过使用纤维蛋白(而不是胶原)支架与TGF-/spl β /和胰岛素培养的化学信号和VE在生物反应器中培养的机械信号的组合来改善瓣膜当量(VEs)的组成和机械性能。

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中国地球物理学会年刊

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