Your search keyword '"Joakim Sundnes"' showing total 6 results

1. A verified and validated moving domain computational fluid dynamics solver with applications to cardiovascular flows

Author

Henrik A. Kjeldsberg, Joakim Sundnes, and Kristian Valen‐Sendstad

Subjects

Computational Theory and Mathematics, Applied Mathematics, Modeling and Simulation, Biomedical Engineering, Molecular Biology, Software

Published

2023

2. Effects of deformation on transmural dispersion of repolarization usingin silicomodels of human left ventricular wedge

Author

E. M. Toledo, Joakim Sundnes, Luis Paulo da Silva Barra, R. Weber dos Santos, Bernardo Martins Rocha, and B. L. de Oliveira

Subjects

medicine.medical_specialty, business.product_category, Materials science, Applied Mathematics, Biomedical Engineering, Mechanics, Deformation (meteorology), Wedge (mechanical device), Coupling (electronics), medicine.anatomical_structure, Amplitude, Computational Theory and Mathematics, Ventricle, Modeling and Simulation, Internal medicine, Solid mechanics, medicine, Cardiology, Repolarization, business, Dispersion (water waves), Molecular Biology, Software

Abstract

Mechanical deformation affects the electrical activity of the heart through multiple feedback loops. The purpose of this work is to study the effect of deformation on transmural dispersion of repolarization and on surface electrograms using an in silico human ventricular wedge. To achieve this purpose, we developed a strongly coupled electromechanical cell model by coupling a human left ventricle electrophysiology model and an active contraction model reparameterized for human cells. This model was then embedded in tissue simulations on the basis of bidomain equations and nonlinear solid mechanics. The coupled model was used to evaluate effects of mechanical deformation on important features of repolarization and electrograms. Our results indicate an increase in the T-wave amplitude of the surface electrograms in simulations that account for the effects of cardiac deformation. This increased T-wave amplitude can be explained by changes to the coupling between neighboring myocytes, also known as electrotonic effect. The thickening of the ventricular wall during repolarization contributes to the decoupling of cells in the transmural direction, enhancing action potential heterogeneity and increasing both transmural repolarization dispersion and T-wave amplitude of surface electrograms. The simulations suggest that a considerable percentage of the T-wave amplitude (15%) may be related to cardiac deformation.

Published

2013

3. Efficient estimation of personalized biventricular mechanical function employing gradient-based optimization

Author

Samuel T. Wall, Ju Le Tan, Henrik Finsberg, Martin Genet, Liang Zhong, Joakim Sundnes, Ce Xi, and Lik Chuan Lee

Subjects

Computational model, Cardiac cycle, Computer science, Estimation theory, Applied Mathematics, 0206 medical engineering, Biomedical Engineering, 02 engineering and technology, Function (mathematics), 030204 cardiovascular system & hematology, 020601 biomedical engineering, Finite element method, 03 medical and health sciences, 0302 clinical medicine, Computational Theory and Mathematics, Modeling and Simulation, Molecular Biology, Contraction (operator theory), Algorithm, Software, Endocardium, Volume (compression)

Abstract

Individually personalized computational models of heart mechanics can be used to estimate important physiological and clinically-relevant quantities that are difficult, if not impossible, to directly measure in the beating heart. Here, we present a novel and efficient framework for creating patient-specific biventricular models using a gradient-based data assimilation method for evaluating regional myocardial contractility and estimating myofiber stress. These simulations can be performed on a regular laptop in less than 2 h and produce excellent fit between measured and simulated volume and strain data through the entire cardiac cycle. By applying the framework using data obtained from 3 healthy human biventricles, we extracted clinically important quantities as well as explored the role of fiber angles on heart function. Our results show that steep fiber angles at the endocardium and epicardium are required to produce simulated motion compatible with measured strain and volume data. We also find that the contraction and subsequent systolic stresses in the right ventricle are significantly lower than that in the left ventricle. Variability of the estimated quantities with respect to both patient data and modeling choices are also found to be low. Because of its high efficiency, this framework may be applicable to modeling of patient specific cardiac mechanics for diagnostic purposes.

Published

2018

4. Preconditioned augmented Lagrangian formulation for nearly incompressible cardiac mechanics

Author

Joventino Oliveira Campos, Joakim Sundnes, Bernardo Martins Rocha, and Rodrigo Weber dos Santos

Subjects

Mathematical optimization, Computer science, Augmented Lagrangian method, Preconditioner, Quantitative Biology::Tissues and Organs, Applied Mathematics, 0206 medical engineering, Biomedical Engineering, 02 engineering and technology, Solver, 020601 biomedical engineering, 01 natural sciences, 010101 applied mathematics, Multigrid method, Computational Theory and Mathematics, Modeling and Simulation, Hyperelastic material, 0101 mathematics, Computational problem, Molecular Biology, Condition number, Software, Stiffness matrix

Abstract

Computational modeling of the heart is a subject of substantial medical and scientific interest, which may contribute to increase the understanding of several phenomena associated with cardiac physiological and pathological states. Modeling the mechanics of the heart have led to considerable insights, but it still represents a complex and a demanding computational problem, especially in a strongly coupled electromechanical setting. Passive cardiac tissue is commonly modeled as hyperelastic and is characterized by quasi-incompressible, orthotropic, and nonlinear material behavior. These factors are known to be very challenging for the numerical solution of the model. The near-incompressibility is known to cause numerical issues such as the well-known locking phenomenon and ill-conditioning of the stiffness matrix. In this work, the augmented Lagrangian method is used to handle the nearly incompressible condition. This approach can potentially improve computational performance by reducing the condition number of the stiffness matrix and thereby improving the convergence of iterative solvers. We also improve the performance of iterative solvers by the use of an algebraic multigrid preconditioner. Numerical results of the augmented Lagrangian method combined with a preconditioned iterative solver for a cardiac mechanics benchmark suite are presented to show its improved performance.

Published

2017

5. High-resolution data assimilation of cardiac mechanics applied to a dyssynchronous ventricle

Author

Joakim Sundnes, Marie E. Rognes, Henrik Finsberg, Gabriel Balaban, Samuel T. Wall, Stian Ross, and Hans Henrik Odland

Subjects

Engineering, 0206 medical engineering, Biomedical Engineering, 02 engineering and technology, computer.software_genre, Synthetic data, 030218 nuclear medicine & medical imaging, Personalization, 03 medical and health sciences, 0302 clinical medicine, Data assimilation, Medical imaging, Set (psychology), Molecular Biology, Image resolution, Computational model, business.industry, Applied Mathematics, 020601 biomedical engineering, Computational Theory and Mathematics, Modeling and Simulation, Artificial intelligence, Data mining, business, computer, Cardiac mechanics, Software

Abstract

Summary Computational models of cardiac mechanics, personalized to a patient, offer access to mechanical information above and beyond direct medical imaging. Additionally, such models can be used to optimize and plan therapies in-silico, thereby reducing risks and improving patient outcome. Model personalization has traditionally been achieved by data assimilation, which is the tuning or optimization of model parameters to match patient observations. Current data assimilation procedures for cardiac mechanics are limited in their ability to efficiently handle high dimensional parameters. This restricts parameter spatial resolution, and thereby the ability of a personalized model to account for heterogeneities that are often present in a diseased or injured heart. In this paper we address this limitation by proposing an adjoint-gradient based data assimilation method that can efficiently handle high-dimensional parameters. We test this procedure on a synthetic data set, and provide a clinical example with a dyssynchronous left ventricle with highly irregular motion. Our results show that the method efficiently handles a high dimensional optimization parameter, and produces an excellent agreement for personalized models to both synthetic and clinical data. This article is protected by copyright. All rights reserved.

Published

2017

6. Space-discretization error analysis and stabilization schemes for conduction velocity in cardiac electrophysiology

Author

Johan Hake, Joakim Sundnes, and Simone Pezzuto

Subjects

Discretization, Applied Mathematics, Numerical analysis, 0206 medical engineering, Biomedical Engineering, Finite difference, Bidomain model, 02 engineering and technology, Grid, 020601 biomedical engineering, 01 natural sciences, Finite element method, 010101 applied mathematics, Nonlinear system, Computational Theory and Mathematics, Control theory, Modeling and Simulation, Applied mathematics, 0101 mathematics, Molecular Biology, Software, Mathematics, Interpolation

Abstract

In cardiac electrophysiology, the propagation of the action potential may be described by a set of reaction-diffusion equations known as the bidomain model. The shape of the solution is determined by a balance of a strong reaction and a relatively weak diffusion, which leads to steep variations in space and time. From a numerical point of view, the sharp spatial gradients may be seen as particularly problematic, because computational grid resolution on the order of 0.1 mm or less is required, yielding considerable computational efforts on human geometries. In this paper, we discuss a number of well-known numerical schemes for the bidomain equation and show how the quality of the solution is affected by the spatial discretization. In particular, we study in detail the effect of discretization on the conduction velocity (CV), which is an important quantity from a physiological point of view. We show that commonly applied finite element techniques tend to overestimate the CV on coarse grids, while it tends to be underestimated by finite difference schemes. Furthermore, the choice of interpolation and discretization scheme for the nonlinear reaction term has a strong impact on the CV. Finally, we exploit the results of the error analysis to propose improved numerical methods, including a stabilized scheme that tends to correct the CV on coarse grids but converges to the correct solution as the grid is refined. Copyright © 2016 John Wiley & Sons, Ltd.

Published

2016