How viscous is the beating heart? Insights from a computational study
DOI10.1007/s00466-022-02180-zzbMath1497.74063OpenAlexW4280549658WikidataQ113326461 ScholiaQ113326461MaRDI QIDQ2171510
Oğuz Ziya Tikenoğulları, Alison L. Marsden, Jiang Yao, Francisco Sahli Costabal, Ellen Kuhl
Publication date: 9 September 2022
Published in: Computational Mechanics (Search for Journal in Brave)
Full work available at URL: https://doi.org/10.1007/s00466-022-02180-z
finite element methodcardiac mechanicsmyocardiumfour-chamber heart modelHolzapfel-Ogden viscoelasticity modelstress-relaxation curve
Finite element methods applied to problems in solid mechanics (74S05) Linear constitutive equations for materials with memory (74D05) Biomechanics (92C10) Biomechanical solid mechanics (74L15)
Related Items (1)
Cites Work
- A fully implicit finite element method for bidomain models of cardiac electromechanics
- On the quasi-incompressible finite element analysis of anisotropic hyperelastic materials
- The generalized Hill model: a kinematic approach towards active muscle contraction
- On non-physical response in models for fiber-reinforced hyperelastic materials
- An anisotropic viscoelastic fibre-matrix model at finite strains: continuum formulation and computational aspects
- A new viscoelastic constitutive model for continuous media at finite thermomechanical changes
- A formulation of elasticity and viscoelasticity for fibre-reinforced material at small and finite strains
- The living heart project: a robust and integrative simulator for human heart function
- Computational modeling of coupled cardiac electromechanics incorporating cardiac dysfunctions
- Active stress vs. active strain in mechanobiology: constitutive issues
- A unified continuum and variational multiscale formulation for fluids, solids, and fluid-structure interaction
- How drugs modulate the performance of the human heart
- Computational cardiology: a modified Hill model to describe the electro-visco-elasticity of the myocardium
- The importance of mechano-electrical feedback and inertia in cardiac electromechanics
- On the implementation of finite deformation gradient-enhanced damage models
- Electromechanics of the heart: a unified approach to the strongly coupled excitation-contraction problem
- Computational modeling of passive myocardium
- Computational modeling of cardiac electrophysiology: A novel finite element approach
- Constitutive modelling of passive myocardium: a structurally based framework for material characterization
This page was built for publication: How viscous is the beating heart? Insights from a computational study
