Quantifying the microstructural and biomechanical changes in the porcine ventricles during growth and remodelling

IF 9.4 1区 医学 Q1 ENGINEERING, BIOMEDICAL
Faizan Ahmad , Shwe Soe , Julie Albon , Rachel Errington , Peter Theobald
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引用次数: 0

Abstract

Cardiac tissue growth and remodelling (G & R) occur in response to the changing physiological demands of the heart after birth. The early shift to pulmonary circulation produces an immediate increase in ventricular workload, causing microstructural and biomechanical changes that serve to maintain overall physiological homoeostasis. Such cardiac G & R continues throughout life. Quantifying the tissue's mechanical and microstructural changes because of G & R is of increasing interest, dovetailing with the emerging fields of personalised and precision solutions. This study aimed to determine equibiaxial, and non-equibiaxial extension, stress-relaxation, and the underlying microstructure of the passive porcine ventricles tissue at four time points spanning from neonatal to adulthood. The three-dimensional microstructure was investigated via two-photon excited fluorescence and second-harmonic generation microscopy on optically cleared tissues, describing the 3D orientation, rotation and dispersion of the cardiomyocytes and collagen fibrils. The results revealed that during biomechanical testing, myocardial ventricular tissue possessed non-linear, anisotropic, and viscoelastic behaviour. An increase in stiffness and viscoelasticity was noted for the left and right ventricular free walls from neonatal to adulthood. Microstructural analyses revealed concomitant increases in cardiomyocyte rotation and dispersion. This study provides baseline data, describing the biomechanical and microstructural changes in the left and right ventricular myocardial tissue during G & R, which should prove valuable to researchers in developing age-specific, constitutive models for more accurate computational simulations.

Statement of significance

There is a dearth of experimental data describing the growth and remodelling of left and right ventricular tissue. The published literature is fragmented, with data reported via different experimental techniques using tissues harvested from a variety of animals, with different gender and ages. This prevents developing a continuum of data spanning birth to death, so limiting the potential that can be leveraged to aid computational modelling and simulations. In this study, equibiaxial, non-equibiaxial, and stress–relaxation data are presented, describing directional-dependent material responses. The biomechanical data is consolidated with equivalent microstructural data, an important element for the development of future material models. Combined, these data describe microstructural and biomechanical changes in the ventricles, spanning G &R from neonatal to adulthood.

Abstract Image

量化猪心室在生长和重塑过程中的微观结构和生物力学变化。
心脏组织生长和重塑(G&R)是对出生后心脏生理需求变化的反应。早期转向肺循环会立即增加心室工作量,导致微观结构和生物力学变化,从而维持整体生理平衡。这种心脏G&R贯穿一生。量化G&R引起的组织的机械和微观结构变化越来越令人感兴趣,这与个性化和精确解决方案的新兴领域相吻合。本研究旨在确定从新生儿到成年的四个时间点的被动猪心室组织的等轴和非等轴拉伸、应力松弛和潜在微观结构。通过双光子激发荧光和二次谐波显微镜在光学清除的组织上研究了三维微观结构,描述了心肌细胞和胶原原纤维的三维定向、旋转和分散。结果表明,在生物力学测试中,心肌心室组织具有非线性、各向异性和粘弹性行为。从新生儿到成年,左心室和右心室游离壁的硬度和粘弹性增加。微观结构分析显示心肌细胞旋转和分散同时增加。这项研究提供了基线数据,描述了G&R期间左心室和右心室心肌组织的生物力学和微观结构变化,这对研究人员开发年龄特异性本构模型以进行更准确的计算模拟具有价值。意义陈述:缺乏描述左心室和右心室组织生长和重塑的实验数据。已发表的文献是零散的,通过不同的实验技术报告的数据使用了从不同性别和年龄的各种动物身上采集的组织。这阻止了开发从出生到死亡的连续数据,从而限制了可用于辅助计算建模和模拟的潜力。在这项研究中,给出了等双轴、非等双轴和应力松弛数据,描述了与方向相关的材料响应。生物力学数据与等效的微观结构数据相结合,这是开发未来材料模型的重要因素。综合起来,这些数据描述了从新生儿到成年的心室微观结构和生物力学变化。
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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来源期刊
Acta Biomaterialia
Acta Biomaterialia 工程技术-材料科学:生物材料
CiteScore
16.80
自引率
3.10%
发文量
776
审稿时长
30 days
期刊介绍: Acta Biomaterialia is a monthly peer-reviewed scientific journal published by Elsevier. The journal was established in January 2005. The editor-in-chief is W.R. Wagner (University of Pittsburgh). The journal covers research in biomaterials science, including the interrelationship of biomaterial structure and function from macroscale to nanoscale. Topical coverage includes biomedical and biocompatible materials.
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