Segregated Algorithms for the Numerical Simulation of Cardiac Electromechanics in the Left Human Ventricle
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Publication:3300479
DOI10.1007/978-3-030-45197-4_3zbMath1446.74210OpenAlexW3040432620MaRDI QIDQ3300479
Antonello Gerbi, Luca Dedè, Alfio M. Quarteroni
Publication date: 29 July 2020
Published in: The Mathematics of Mechanobiology (Search for Journal in Brave)
Full work available at URL: https://doi.org/10.1007/978-3-030-45197-4_3
Finite element methods applied to problems in solid mechanics (74S05) Electromagnetic effects in solid mechanics (74F15) Finite difference methods applied to problems in solid mechanics (74S20) Biomechanics (92C10) Biomechanical solid mechanics (74L15) Computational methods for problems pertaining to biology (92-08)
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Cites Work
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- Joint influence of transmural heterogeneities and wall deformation on cardiac bioelectrical activity: a simulation study
- A fully implicit finite element method for bidomain models of cardiac electromechanics
- Space-time and ALE-VMS techniques for patient-specific cardiovascular fluid-structure interaction modeling
- Computational model of three-dimensional cardiac electromechanics
- Quasi-incompressible finite elasticity in principal stretches. Continuum basis and numerical algorithms
- Loss of mass and performance in skeletal muscle tissue: a continuum model
- INTERNODES: an accurate interpolation-based method for coupling the Galerkin solutions of PDEs on subdomains featuring non-conforming interfaces
- Thermodynamically consistent orthotropic activation model capturing ventricular systolic wall thickening in cardiac electromechanics
- Facsi: a block parallel preconditioner for fluid-structure interaction in hemodynamics
- Minimal model for human ventricular action potentials in tissue
- Active stress vs. active strain in mechanobiology: constitutive issues
- A monolithic algorithm for the simulation of cardiac electromechanics in the human left ventricle
- The importance of mechano-electrical feedback and inertia in cardiac electromechanics
- Integrated heart -- coupling multiscale and multiphysics models for the simulation of the cardiac function
- Parallel multilevel solvers for the cardiac electro-mechanical coupling
- Anatomically accurate high resolution modeling of human whole heart electromechanics: A strongly scalable algebraic multigrid solver method for nonlinear deformation
- A monolithic approach to fluid-composite structure interaction
- Mathematical cardiac electrophysiology
- Algebraic fractional-step schemes with spectral methods for the incompressible Navier--Stokes equations
- Electromechanics of the heart: a unified approach to the strongly coupled excitation-contraction problem
- Bioelectrical effects of mechanical feedbacks in a strongly coupled cardiac electro-mechanical model
- An active strain electromechanical model for cardiac tissue
- Mathematical modelling of active contraction in isolated cardiomyocytes
- Electromechanical Coupling in Cardiac Dynamics: The Active Strain Approach
- DECOUPLED SCHWARZ ALGORITHMS FOR IMPLICIT DISCRETIZATIONS OF NONLINEAR MONODOMAIN AND BIDOMAIN SYSTEMS
- On the Development of Volumetric Strain Energy Functions
- Constitutive modelling of passive myocardium: a structurally based framework for material characterization
- The discrete maximum principle for stabilized finite element methods
- The architecture of the heart: a data–based model
- Mathematical Modelling of the Human Cardiovascular System
- Computational electrocardiology: mathematical and numerical modeling
- Influence of myocardial fiber/sheet orientations on left ventricular mechanical contraction
