胎猪心肌被动刚度双心室双轴力学试验及本构模型。

Meifeng Ren, C. Ong, M. Buist, C. Yap
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引用次数: 1

摘要

胎儿心脏力学功能的评估对于确定先天性心脏病的预后和制定后续治疗和管理决策变得越来越重要。有限元(FE)建模可以潜在地提供胎儿心脏的详细信息,并帮助进行虚拟干预,以协助预测结果和支持临床决策。先前的FE研究已经使人们对健康和患病胎儿心脏的生物力学有了更好的了解。然而,到目前为止,胎儿心肌的力学特性还没有很好地表征,这限制了这种模型的可靠性。在这里,我们通过双轴力学测试来表征晚期胎儿和新生儿猪心脏的被动力学特性,作为人类胎儿心脏力学特性的替代品。我们使用的样本来自右心室和左心室在妊娠后期从妊娠85天到出生。随后使用横向各向同性的fung型模型和humphrey型模型进行本构建模,使用与组织学鉴定的纤维取向。我们发现机械刚度在所有年龄组和左右心室样本之间没有显著差异。这可能是由于胎儿心脏的左心室和右心室压力相似,以及这些孕晚期的妊娠成熟度相似。因此,我们建议在未来的建模工作中使用本构模型来计算组织的平均应力-应力行为。此外,我们表征了刚度的可变性,以告知此类工作。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Biventricular biaxial mechanical testing and constitutive modelling of fetal porcine myocardium passive stiffness.
The evaluation of fetal heart mechanical function is becoming increasingly important for determining the prognosis and making subsequent decisions on the treatment and management of congenital heart diseases. Finite Element (FE) modelling can potentially provide detailed information on fetal hearts, and help perform virtual interventions to assist in predicting outcomes and supporting clinical decisions. Previous FE studies have enabled an improved understanding of healthy and diseased fetal heart biomechanics. However, to date, the mechanical properties of the fetal myocardium have not been well characterized which limits the reliability of such modelling. Here, we characterize the passive mechanical properties of late fetal and neonatal porcine hearts via biaxial mechanical testing as a surrogate for human fetal heart mechanical properties. We used samples from both the right and left ventricles over the late gestational period from 85 days of gestation to birth. Constitutive modelling was subsequently performed with a transversely isotropic Fung-type model and a Humphrey-type model, using fiber orientations identified with histology. We found no significant difference in mechanical stiffness across all age groups and between the right and left ventricular samples. This was likely due to the similarity in LV and RV pressures in the fetal heart, and similar gestational maturity across these late gestational ages. We thus recommend using the constitutive model for the average stress-stress behaviour of the tissues in future modelling work. Furthermore, we characterized the variability of the stiffness to inform such work.
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