The estimation of material parameters in constitutive models for soft biological materials such as myocardium is a challenging problem due to the complex behavior of the material. Here we present a systematic scheme to solve the inverse problem of estimating material parameters from experimentally observed deformation. This scheme couples a genetic algorithm with nonlinear finite element analysis. The approach is very general and can be applied to a wide range of inverse boundary value problems. Effectiveness of this scheme is demonstrated through examples involving two-dimensional and three-dimensional hyperelastic material models. Finally, a problem involving variation of material parameter through the ventricular wall is investigated
The mouse is an important model for theoretical-experimental cardiac research, and biophysically bas...
This work deals with the computational modeling of passive myocardial tissue within the framework of...
A central problem in biomechanical studies of personalized human left ventricular (LV) modelling is ...
The estimation of material parameters in constitutive models for soft biological materials such as m...
Determining the unknown material parameters of intact ventricular myocardium can be challenging due ...
In this paper we present the results of a detailed study of a systematic numerical scheme for estima...
In this thesis numerical methods combining evolutionary optimization algorithms and finite element a...
Modern breakthroughs in biomedical engineering, computer science, and data mining have created new o...
Quantitative measurement of the material properties (eg, stiffness) of biological tissues is poised ...
Considering the nonlinear hyperelastic or viscoelastic nature of soft tissues has an important effec...
A clinically applicable approach to estimate the in vivo elastic material properties of the heart wa...
International audienceImportance of material parameters and strain energy function on the wall stres...
Abstract The objective of this study is to identify the dynamic material properties of human passive...
This paper presents a novel methodology to in-vivo estimate the elastic constants of a constitutive ...
Heart ventricular mechanics has been investigated intensively in the last four decades. The passive ...
The mouse is an important model for theoretical-experimental cardiac research, and biophysically bas...
This work deals with the computational modeling of passive myocardial tissue within the framework of...
A central problem in biomechanical studies of personalized human left ventricular (LV) modelling is ...
The estimation of material parameters in constitutive models for soft biological materials such as m...
Determining the unknown material parameters of intact ventricular myocardium can be challenging due ...
In this paper we present the results of a detailed study of a systematic numerical scheme for estima...
In this thesis numerical methods combining evolutionary optimization algorithms and finite element a...
Modern breakthroughs in biomedical engineering, computer science, and data mining have created new o...
Quantitative measurement of the material properties (eg, stiffness) of biological tissues is poised ...
Considering the nonlinear hyperelastic or viscoelastic nature of soft tissues has an important effec...
A clinically applicable approach to estimate the in vivo elastic material properties of the heart wa...
International audienceImportance of material parameters and strain energy function on the wall stres...
Abstract The objective of this study is to identify the dynamic material properties of human passive...
This paper presents a novel methodology to in-vivo estimate the elastic constants of a constitutive ...
Heart ventricular mechanics has been investigated intensively in the last four decades. The passive ...
The mouse is an important model for theoretical-experimental cardiac research, and biophysically bas...
This work deals with the computational modeling of passive myocardial tissue within the framework of...
A central problem in biomechanical studies of personalized human left ventricular (LV) modelling is ...
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