心脏瓣膜如何进化以适应极端压力系统：长颈鹿心脏瓣膜的形态学和生物力学特性

How Heart Valves Evolve to Adapt to an Extreme-Pressure System: Morphologic and Biomechanical Properties of Giraffe Heart Valves.

作者信息

Amstrup Funder Jonas, Christian Danielsen Carl, Baandrup Ulrik, Martin Bibby Bo, Carl Andelius Ted, Toft Brøndum Emil, Wang Tobias, Michael Hasenkam J

机构信息

Department of Surgery, Aarhus University Hospital, Aarhus, Denmark.

Department of Biomedicin, Aarhus University, Aarhus, Denmark.

出版信息

J Heart Valve Dis. 2017 Jan;26(1):63-71.

PMID:28544833

Abstract

BACKGROUND

Heart valves which exist naturally in an extreme-pressure system must have evolved in a way to resist the stresses of high pressure. Giraffes are interesting as they naturally have a blood pressure twice that of humans. Thus, knowledge regarding giraffe heart valves may aid in developing techniques to design improved pressure-resistant biological heart valves.

METHODS

Heart valves from 12 giraffes and 10 calves were explanted and subjected to either biomechanical or morphological examinations. Strips from the heart valves were subjected to cyclic loading tests, followed by failure tests. Thickness measurements and analyses of elastin and collagen content were also made. Valve specimens were stained with hematoxylin and eosin, elastic van Gieson stain, Masson's trichrome and Fraser-Lendrum stain, as well as immunohistochemical reactions for morphological examinations.

RESULTS

The aortic valve was shown to be 70% (95% CI 42-103%) stronger in the giraffe than in its bovine counterpart (p <0.001). No significant difference was found between mitral or pulmonary valves. After normalization for collagen, no significant differences were found in strength between species. The giraffe aortic valve was found to be significantly stiffer than the bovine aortic valve (p <0.001), with no significant difference between mitral and pulmonary valves. On a dry weight basis, the aortic (10.9%), pulmonary (4.3%), and mitral valves (9.6%) of giraffes contained significantly more collagen than those of calves. The elastin contents of the pulmonary valves (2.5%) and aortic valves (1.5%) were also higher in giraffes.

CONCLUSIONS

The greater strength of the giraffe aortic valve is most likely due to a compact collagen construction. Both, collagen and elastin contents were higher in giraffes than in calves, which would make giraffe valves more resistant to the high-pressure forces. However, collagen also stiffens and thickens the valves. The mitral leaflets showed similar (but mostly insignificant) trends in strength, stiffness, and collagen content.

摘要

背景

自然存在于极端压力系统中的心脏瓣膜必定以某种方式进化以抵抗高压应力。长颈鹿很有趣，因为它们的血压自然是人类的两倍。因此，关于长颈鹿心脏瓣膜的知识可能有助于开发设计改进的耐压生物心脏瓣膜的技术。

方法

取出12只长颈鹿和10头小牛的心脏瓣膜，进行生物力学或形态学检查。心脏瓣膜的条带进行循环加载试验，然后进行失效试验。还进行了厚度测量以及弹性蛋白和胶原蛋白含量的分析。瓣膜标本用苏木精和伊红染色、弹性范吉森染色、马森三色染色和弗雷泽 - 伦德鲁姆染色，以及用于形态学检查的免疫组织化学反应。

结果

长颈鹿的主动脉瓣比牛的主动脉瓣强70%（95%可信区间42 - 103%）（p <0.001）。二尖瓣或肺动脉瓣之间未发现显著差异。在胶原蛋白标准化后，物种之间的强度没有显著差异。发现长颈鹿的主动脉瓣比牛的主动脉瓣明显更硬（p <0.001），二尖瓣和肺动脉瓣之间没有显著差异。以干重计，长颈鹿的主动脉瓣（10.9%）、肺动脉瓣（4.3%）和二尖瓣（9.6%）含有的胶原蛋白明显多于小牛的。长颈鹿的肺动脉瓣（2.5%）和主动脉瓣（1.5%）的弹性蛋白含量也更高。