Continuum strain energy density functions are developed for soft biological tissues that possess slender, fibrillar components. The treatment is based on the model of an elastica, which is our fine scale model, and is homogenized in a simple fashion to obtain a continuum strain energy density function. Notably, we avoid solving the exact, fourth-order, non-linear, partial differential equation for deformation of the elastica by resorting to other assumptions, kinematic and energetic, on the response of individual, elastica-like fibrils. The formulation, discussion of responses of different models and comparison with experiment are presented
Experiments on brain samples under multiaxial loading have shown that human brain tissue is both ext...
This paper presents the development of a two-scale anisotropic hyperelastic material model whose mic...
The development of a conceptual framework to test different viscoelastic constitutive laws is presen...
© 2020 Elsevier. This manuscript version is made available under the CC-BY-NC-ND 4.0 license http://...
Strain measures consistent with the classical, infinitesimal form of the strain-energy function are ...
Extensive research has been performed in the past decades to study the behavior of soft biological t...
In this work, a continuum constitutive framework for the mechanical modelling of soft tissues that i...
In this contribution, a non-linear viscoelastic anisotropic model for soft biological tissues is pre...
Despite distinct mechanical functions, biological soft tissues have a common microstructure in which...
AbstractIn this paper, an exponential framework for strain energy density functions of elastomers an...
International audienceMany soft tissues are naturally made of a matrix and fibres that present some ...
AbstractThis paper deals with the formulation of rigorous numerical methods for the stress analysis,...
International audienceConstitutive modelling of soft biological tissues has been the topic of abunda...
AbstractA new strain energy function for the hyperelastic modelling of ligaments and tendons based o...
Microstructure-based constitutive models have been adopted in recent studies of non-linear mechanica...
Experiments on brain samples under multiaxial loading have shown that human brain tissue is both ext...
This paper presents the development of a two-scale anisotropic hyperelastic material model whose mic...
The development of a conceptual framework to test different viscoelastic constitutive laws is presen...
© 2020 Elsevier. This manuscript version is made available under the CC-BY-NC-ND 4.0 license http://...
Strain measures consistent with the classical, infinitesimal form of the strain-energy function are ...
Extensive research has been performed in the past decades to study the behavior of soft biological t...
In this work, a continuum constitutive framework for the mechanical modelling of soft tissues that i...
In this contribution, a non-linear viscoelastic anisotropic model for soft biological tissues is pre...
Despite distinct mechanical functions, biological soft tissues have a common microstructure in which...
AbstractIn this paper, an exponential framework for strain energy density functions of elastomers an...
International audienceMany soft tissues are naturally made of a matrix and fibres that present some ...
AbstractThis paper deals with the formulation of rigorous numerical methods for the stress analysis,...
International audienceConstitutive modelling of soft biological tissues has been the topic of abunda...
AbstractA new strain energy function for the hyperelastic modelling of ligaments and tendons based o...
Microstructure-based constitutive models have been adopted in recent studies of non-linear mechanica...
Experiments on brain samples under multiaxial loading have shown that human brain tissue is both ext...
This paper presents the development of a two-scale anisotropic hyperelastic material model whose mic...
The development of a conceptual framework to test different viscoelastic constitutive laws is presen...