Several experiments have demonstrated the existence of an electro-mechanical effect in many biological tissues and hydrogels, and its actual influence on growth, migration, and pattern formation. Here, to model these interactions and capture some growth phenomena found in Nature, we extend volume growth theory to account for an electro-elasticity coupling. Based on the multiplicative decomposition, we present a general analysis of isotropic growth and pattern formation of electro-elastic solids under external mechanical and electrical fields. As an example, we treat the case of a tubular structure to illustrate an electromechanically guided growth affected by axial strain and radial voltage. Our numerical results show that a high voltage ca...
This paper addresses the possible mechanism of stretch on cell electrochemical potential change, bas...
The morphogenesis of organs necessarily involves mechanical interactions and changes in mechanical p...
Recent evidence has revealed the role of mechanical cues in the development of shapes in organisms. ...
Several experiments have demonstrated the existence of an electro-mechanical effect in many biologic...
Electro-mechanical response exists in growing materials such as biological tissues and hydrogels, in...
Initial residual stress is omnipresent in biological tissues and soft matter, and can affect growth-...
Many living biological tissues are known to grow in response to their mechanical environment, such a...
International audienceConstrained growth processes in living materials result in a complex distribut...
Many biological systems are coated by thin films for protection, selective absorption, or transmembr...
ABSTRACT Surface patterns can emerge during growth of anisotropic tissues because of surface bucklin...
International audienceIn a recent paper, Coen et al. [2004] proposed a qualitative framework to stud...
Soft tissues are complex materials with typical nonlinear, anisotropic, inhomogeneous behaviors subj...
The generation of an effective method for stimulating neuronal growth in specific directions, along ...
This chapter is concerned with the modelling of growth processes in the framework of continuum mecha...
This paper addresses the possible mechanism of stretch on cell electrochemical potential change, bas...
The morphogenesis of organs necessarily involves mechanical interactions and changes in mechanical p...
Recent evidence has revealed the role of mechanical cues in the development of shapes in organisms. ...
Several experiments have demonstrated the existence of an electro-mechanical effect in many biologic...
Electro-mechanical response exists in growing materials such as biological tissues and hydrogels, in...
Initial residual stress is omnipresent in biological tissues and soft matter, and can affect growth-...
Many living biological tissues are known to grow in response to their mechanical environment, such a...
International audienceConstrained growth processes in living materials result in a complex distribut...
Many biological systems are coated by thin films for protection, selective absorption, or transmembr...
ABSTRACT Surface patterns can emerge during growth of anisotropic tissues because of surface bucklin...
International audienceIn a recent paper, Coen et al. [2004] proposed a qualitative framework to stud...
Soft tissues are complex materials with typical nonlinear, anisotropic, inhomogeneous behaviors subj...
The generation of an effective method for stimulating neuronal growth in specific directions, along ...
This chapter is concerned with the modelling of growth processes in the framework of continuum mecha...
This paper addresses the possible mechanism of stretch on cell electrochemical potential change, bas...
The morphogenesis of organs necessarily involves mechanical interactions and changes in mechanical p...
Recent evidence has revealed the role of mechanical cues in the development of shapes in organisms. ...