Minimum design requirements for a poroelastic mimic of articular cartilage.

W. Tan, A. Moore, M. Stevens
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引用次数: 3

Abstract

The exceptional functional performance of articular cartilage (load-bearing and lubrication) is attributed to its poroelastic structure and resulting interstitial fluid pressure. Despite this, there remains no engineered cartilage repair material capable of achieving physiologically relevant poroelasticity. In this work we develop in silico models to guide the design approach for poroelastic mimics of articular cartilage. We implement the constitutive models in FEBio, a PDE solver for multiphasic mechanics problems in biological and soft materials. We investigate the influence of strain rate, boundary conditions at the contact interface, and fiber modulus on the reaction force and load sharing between the solid and fluid phases. The results agree with the existing literature that when fibers are incorporated the fraction of load supported by fluid pressure is greatly amplified and increases with the fiber modulus. This result demonstrates that a stiff fibrous phase is a primary design requirement for poroelastic mimics of articular cartilage. The poroelastic model is fit to experimental stress-relaxation data from bovine and porcine cartilage to determine if sufficient design constraints have been identified. In addition, we fit experimental data from FiHy™, an engineered material which is claimed to be poroelastic. The fiber-reinforced poroelastic model was able to capture the primary physics of these materials and demonstrates that FiHy™ is beginning to approach a cartilage-like poroelastic response. We also develop a fiber-reinforced poroelastic model with a bonded interface (rigid contact) to fit stress relaxation data from an osteochondral explant and FiHy™ + bone substitute. The model fit quality is similar for both the chondral and osteochondral configurations and clearly captures the first order physics. Based on this, we propose that physiological poroelastic mimics of articular cartilage should be developed under a fiber-reinforced poroelastic framework.
关节软骨多孔弹性模拟物的最低设计要求。
关节软骨的特殊功能性能(承载和润滑)归因于其多孔弹性结构和由此产生的间质流体压力。尽管如此,仍然没有能够实现生理相关孔隙弹性的工程软骨修复材料。在这项工作中,我们开发了计算机模型,以指导关节软骨多孔弹性模拟的设计方法。我们在FEBio中实现了本构模型,FEBio是一个用于生物和软材料多相力学问题的PDE求解器。我们研究了应变速率、接触界面的边界条件和纤维模量对固相和液相之间的反作用力和载荷分担的影响。结果与现有文献一致,即当加入纤维时,流体压力支撑的载荷份额大大放大,并随着纤维模量的增加而增加。这一结果表明,坚硬的纤维相是关节软骨多孔弹性模拟物的主要设计要求。多孔弹性模型适用于牛和猪软骨的实验应力松弛数据,以确定是否已经确定了足够的设计约束。此外,我们拟合了FiHy的实验数据™, 一种声称具有多孔弹性的工程材料。纤维增强多孔弹性模型能够捕捉到这些材料的主要物理特性,并证明FiHy™ 开始接近软骨样的多孔弹性反应。我们还开发了一个具有粘结界面(刚性接触)的纤维增强多孔弹性模型,以拟合骨软骨外植体和FiHy的应力松弛数据™+骨替代品。软骨和骨软骨配置的模型拟合质量相似,并且清楚地捕捉到了一阶物理。基于此,我们提出关节软骨的生理多孔弹性模拟物应该在纤维增强多孔弹性框架下开发。
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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