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 mat...
The purpose of the research was to develop a quantitative method which could be used to obtain a cle...
In this paper we summarize a general continuum mechanical theory that takes account of growth in mat...
Some of the key factors that regulate growth and remodeling of tissues are fundamentally mechanical....
<div><p>The purpose of this manuscript is to establish a unified theory of porohyperelasticity with ...
The purpose of this manuscript is to establish a unified theory of porohyperelasticity with transpor...
The theory of morpho-poroelasticity is applied to tumor growth. This allows for the modeling of perm...
Growth in nature is associated with the development of residual stresses and is in general heterogen...
In this paper we propose a simple model for fluid solid interaction in a cylindrical thin-walled art...
This paper outlines the framework of a porous flow mixture theory for the mathematical modelling of ...
International audienceBackground. Constitutive models of the mechanical response of soft tissues hav...
A novel framework for simulating growth and remodelling (G&R) of a fibre-reinforced artery, incl...
Within the medical community, there has been increasing interest in understanding material growth in...
The final publication is available at Springer via http://dx.doi.org/10.1007/s00466-013-0959-zArteri...
In this paper we propose a new mathematical model for describing the complex interplay between skin ...
AbstractA novel framework for simulating growth and remodelling (G&R) of a fibre-reinforced artery, ...
The purpose of the research was to develop a quantitative method which could be used to obtain a cle...
In this paper we summarize a general continuum mechanical theory that takes account of growth in mat...
Some of the key factors that regulate growth and remodeling of tissues are fundamentally mechanical....
<div><p>The purpose of this manuscript is to establish a unified theory of porohyperelasticity with ...
The purpose of this manuscript is to establish a unified theory of porohyperelasticity with transpor...
The theory of morpho-poroelasticity is applied to tumor growth. This allows for the modeling of perm...
Growth in nature is associated with the development of residual stresses and is in general heterogen...
In this paper we propose a simple model for fluid solid interaction in a cylindrical thin-walled art...
This paper outlines the framework of a porous flow mixture theory for the mathematical modelling of ...
International audienceBackground. Constitutive models of the mechanical response of soft tissues hav...
A novel framework for simulating growth and remodelling (G&R) of a fibre-reinforced artery, incl...
Within the medical community, there has been increasing interest in understanding material growth in...
The final publication is available at Springer via http://dx.doi.org/10.1007/s00466-013-0959-zArteri...
In this paper we propose a new mathematical model for describing the complex interplay between skin ...
AbstractA novel framework for simulating growth and remodelling (G&R) of a fibre-reinforced artery, ...
The purpose of the research was to develop a quantitative method which could be used to obtain a cle...
In this paper we summarize a general continuum mechanical theory that takes account of growth in mat...
Some of the key factors that regulate growth and remodeling of tissues are fundamentally mechanical....