The effects of hammer pressure on cellular response in a porcine heart valve tissue.

Cardiovascular Engineering (dordrecht, Netherlands) Pub Date : 2010-09-01 DOI:10.1007/s10558-010-9101-4

Jason P Haley, Hadi Mohammadi, Derek R Boughner

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引用次数: 5

Abstract

Our objective was to design, develop, characterize and validate a prototype device for testing the response of aortic valve tissue to impact forces. With each cardiac cycle, the aortic valve, on closure, is subjected to a substantial impact force and the ability of valvular interstitial cells to withstand such forces without apoptosis has not been examined. Our aim was to correlate impact force with apoptosis, identifying the latter using a terminal transferase dUTP nick end-labelling (Tunel) assay. With our drop tower design, we created reproducible impact forces on heart valve tissue resulting in cellular trauma. The reliability of the impact tester design were verified and results showed that normal tissue can withstand impact forces more than 30× greater than the physiological forces to which the tissue is normally exposed. This provides a wide safety margin and indicates that bioengineered aortic valve tissue should have similar properties if it is to withstand physiologic forces long term.

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锤击压力对猪心脏瓣膜组织细胞反应的影响。

我们的目标是设计、开发、表征和验证一个原型装置，用于测试主动脉瓣组织对冲击力的反应。在每个心动周期中，主动脉瓣关闭时都受到巨大的冲击力，而瓣间质细胞承受这种力而不发生凋亡的能力尚未得到检验。我们的目的是将冲击力与细胞凋亡联系起来，使用末端转移酶dUTP缺口末端标记(Tunel)试验鉴定细胞凋亡。通过我们的跌落塔设计，我们在心脏瓣膜组织上产生了可重复的冲击力，导致细胞损伤。验证了冲击试验机设计的可靠性，结果表明，正常组织所能承受的冲击力比正常组织所承受的生理力大30倍以上。这提供了广泛的安全范围，并表明生物工程主动脉瓣组织如果要长期承受生理力量，应该具有类似的特性。

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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Cardiovascular Engineering (dordrecht, Netherlands)

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