A Bimodular Polyconvex Anisotropic Strain Energy Function for Articular Cartilage

Stephen M. Klisch, California Polytechnic State University - San Luis Obispo

Article comments

DOI: http://dx.doi.org/10.1115/1.2486225.

Copyright © 2007 by ASME. Please contact ASME at permissions@asme.org for permission to reuse this article. Publisher website: http://store.asme.org.

Abstract

A strain energy function for finite deformations is developed that has the capability to describe the nonlinear, anisotropic, and asymmetric mechanical response that is typical of articular cartilage. In particular, the bimodular feature is employed by including strain energy terms that are only mechanically active when the corresponding fiber directions are in tension. Furthermore, the strain energy function is a polyconvex function of the deformation gradient tensor so that it meets material stability criteria. A novel feature of the model is the use of bimodular and polyconvex “strong interaction terms” for the strain invariants of orthotropic materials. Several regression analyses are performed using a hypothetical experimental dataset that captures the anisotropic and asymmetric behavior of articular cartilage. The results suggest that the main advantage of a model employing the strong interaction terms is to provide the capability for modeling anisotropic and asymmetric Poisson's ratios, as well as axial stress–axial strain responses, in tension and compression for finite deformations.