Initial residual stress is omnipresent in biological tissues and soft matter, and can affect growth-induced pattern selection significantly. Here we demonstrate this effect experimentally by letting soft tubes grow in the presence or absence of initial residual stress and by observing different growth pattern evolutions. These experiments motivate us to model the mechanisms at play when a growing bilayer tubular organ spontaneously displays buckling patterns on its inner surface. We demonstrate that not only differential growth, geometry and elasticity, but also initial residual stress distribution, exert a notable influence on these pattern phenomena. Prescribing an initial residual stress distribution offers an alternative or a more effec...
Biological growth is often driven by mechanical cues, such as changes in external pressure or tensil...
We study theoretically the morphologies of biological tubes affected by various pathologies. When ep...
International audienceLiving tissues are naturally prestrained (or, equivalently, residually stresse...
Initial residual stress is omnipresent in biological tissues and soft matter, and can affect growth-...
Residual stress is ubiquitous and indispensable in most biological and artificial materials, where i...
Many biological tissues and organisms are in a state of residual stress, which should be considered ...
In this paper we summarize a general continuum mechanical theory that takes account of growth in mat...
Many living biological tissues are known to grow in response to their mechanical environment, such a...
The multiplicative decomposition model is widely employed for predicting residual stresses and morph...
International audienceConstrained growth processes in living materials result in a complex distribut...
The multiplicative decomposition model is widely employed for predicting residual stresses and morph...
Soft tissues are complex materials with typical nonlinear, anisotropic, inhomogeneous behaviors subj...
Several experiments have demonstrated the existence of an electro-mechanical effect in many biologic...
Growth in nature is associated with the development of residual stresses and is in general heterogen...
Biological growth is often driven by mechanical cues, such as changes in external pressure or tensil...
Biological growth is often driven by mechanical cues, such as changes in external pressure or tensil...
We study theoretically the morphologies of biological tubes affected by various pathologies. When ep...
International audienceLiving tissues are naturally prestrained (or, equivalently, residually stresse...
Initial residual stress is omnipresent in biological tissues and soft matter, and can affect growth-...
Residual stress is ubiquitous and indispensable in most biological and artificial materials, where i...
Many biological tissues and organisms are in a state of residual stress, which should be considered ...
In this paper we summarize a general continuum mechanical theory that takes account of growth in mat...
Many living biological tissues are known to grow in response to their mechanical environment, such a...
The multiplicative decomposition model is widely employed for predicting residual stresses and morph...
International audienceConstrained growth processes in living materials result in a complex distribut...
The multiplicative decomposition model is widely employed for predicting residual stresses and morph...
Soft tissues are complex materials with typical nonlinear, anisotropic, inhomogeneous behaviors subj...
Several experiments have demonstrated the existence of an electro-mechanical effect in many biologic...
Growth in nature is associated with the development of residual stresses and is in general heterogen...
Biological growth is often driven by mechanical cues, such as changes in external pressure or tensil...
Biological growth is often driven by mechanical cues, such as changes in external pressure or tensil...
We study theoretically the morphologies of biological tubes affected by various pathologies. When ep...
International audienceLiving tissues are naturally prestrained (or, equivalently, residually stresse...