A Finite Element Model for Mixed Porohyperelasticity with Transport, Swelling, and Growth.

Michelle Hine Armstrong,Bruce R Simon,Jonathan P Vande Geest,Ellen Kuhl,Adrián Buganza Tepole

doi:10.1371/journal.pone.0152806

Michelle Hine Armstrong, Bruce R Simon + Show 3 more

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https://doi.org/10.1371/journal.pone.0152806

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Abstract

The purpose of this manuscript is to establish a unified theory of porohyperelasticity with transport and growth and to demonstrate the capability of this theory using a finite element model developed in MATLAB. We combine the theories of volumetric growth and mixed porohyperelasticity with transport and swelling (MPHETS) to derive a new method that models growth of biological soft tissues. The conservation equations and constitutive equations are developed for both solid-only growth and solid/fluid growth. An axisymmetric finite element framework is introduced for the new theory of growing MPHETS (GMPHETS). To illustrate the capabilities of this model, several example finite element test problems are considered using model geometry and material parameters based on experimental data from a porcine coronary artery. Multiple growth laws are considered, including time-driven, concentration-driven, and stress-driven growth. Time-driven growth is compared against an exact analytical solution to validate the model. For concentration-dependent growth, changing the diffusivity (representing a change in drug) fundamentally changes growth behavior. We further demonstrate that for stress-dependent, solid-only growth of an artery, growth of an MPHETS model results in a more uniform hoop stress than growth in a hyperelastic model for the same amount of growth time using the same growth law. This may have implications in the context of developing residual stresses in soft tissues under intraluminal pressure. To our knowledge, this manuscript provides the first full description of an MPHETS model with growth. The developed computational framework can be used in concert with novel in-vitro and in-vivo experimental approaches to identify the governing growth laws for various soft tissues.

Highlights

The theories of mixed porohyperelasticity and growth have developed separately, and our laboratory has been working to unite them into one combined theory
To illustrate the capabilities of the growing MPHETS (GMPHETS) model, we consider a few different growth laws applied to a Neo-Hookean material
For stress-dependent growth, we show that after growth the gradient of the effective hoop stress for an mixed porohyperelasticity with transport and swelling (MPHETS) model of an axisymmetric cylinder is lower than the gradient in hoop stress for a hyperelastic (HE) model

Summary

Introduction

The theories of mixed porohyperelasticity and growth have developed separately, and our laboratory has been working to unite them into one combined theory. Porohyperelasticity and biphasic/triphasic theory have long been used to describe the biomechanical response of hard and soft tissues [1,2,3,4]. In this paper we will combine the theory of mixed porohyperelasticity with transport and swelling (MPHETS) [1, 3, 13,14,15] with volumetric growth [6, 16,17,18]. Many soft tissues consist of a porous solid skeleton that is fully saturated by an interstitial fluid and as such can be adequately modled as a fully saturated porohyperelastic (PHE) material. One may wish to track the behavior of a dissolved species representing a drug, growth factor, or naturally occurring cytokines, which can be done utilizing a few different approaches [1,2,3,4, 19,20,21,22,23]

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