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Literature DB >> 21303740

Efficient computational methods for strongly coupled cardiac electromechanics.

Sander Land¹, Steven A Niederer, Nicolas P Smith.

Abstract

Strongly coupled cardiac electromechanical models can further our understanding of the relative importance of feedback mechanisms in the heart, but computational challenges currently remain a major obstacle, which limit their widespread use. To address this issue, we present a set of efficient computational methods including an efficient adaptive cell model integration scheme and a solution method for the monodomain equations that maintains high conduction velocity for time steps greater than 0.1 ms. We also present a novel method for increasing the efficiency of simulating electromechanical coupling, which shows a significant reduction in computational cost of the mechanical component on a personalized left ventricular geometry with an active contraction cell model reparametrized for human cells.

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Year: 2011 PMID： 21303740 DOI： 10.1109/TBME.2011.2112359

Source DB: PubMed Journal: IEEE Trans Biomed Eng ISSN： 0018-9294 Impact factor: 4.538

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Cited

26 in total

Review 1. At the heart of computational modelling.

Authors: S A Niederer; N P Smith
Journal: J Physiol Date: 2012-01-23 Impact factor: 5.182

2. Verification of cardiac tissue electrophysiology simulators using an N-version benchmark.

Authors: Steven A Niederer; Eric Kerfoot; Alan P Benson; Miguel O Bernabeu; Olivier Bernus; Chris Bradley; Elizabeth M Cherry; Richard Clayton; Flavio H Fenton; Alan Garny; Elvio Heidenreich; Sander Land; Mary Maleckar; Pras Pathmanathan; Gernot Plank; José F Rodríguez; Ishani Roy; Frank B Sachse; Gunnar Seemann; Ola Skavhaug; Nic P Smith
Journal: Philos Trans A Math Phys Eng Sci Date: 2011-11-13 Impact factor: 4.226

3. Towards causally cohesive genotype-phenotype modelling for characterization of the soft-tissue mechanics of the heart in normal and pathological geometries.

Authors: Øyvind Nordbø; Arne B Gjuvsland; Anders Nermoen; Sander Land; Steven Niederer; Pablo Lamata; Jack Lee; Nicolas P Smith; Stig W Omholt; Jon Olav Vik
Journal: J R Soc Interface Date: 2015-05-06 Impact factor: 4.118

4. Quantifying inter-species differences in contractile function through biophysical modelling.

Authors: Kristin Tøndel; Sander Land; Steven A Niederer; Nicolas P Smith
Journal: J Physiol Date: 2015-01-20 Impact factor: 5.182

5. Improved discretisation and linearisation of active tension in strongly coupled cardiac electro-mechanics simulations.

Authors: J Sundnes; S Wall; H Osnes; T Thorvaldsen; A D McCulloch
Journal: Comput Methods Biomech Biomed Engin Date: 2012-07-16 Impact factor: 1.763

Efficient computational methods for strongly coupled cardiac electromechanics.

Review 1. At the heart of computational modelling.

2. Verification of cardiac tissue electrophysiology simulators using an N-version benchmark.

3. Towards causally cohesive genotype-phenotype modelling for characterization of the soft-tissue mechanics of the heart in normal and pathological geometries.

4. Quantifying inter-species differences in contractile function through biophysical modelling.

5. Improved discretisation and linearisation of active tension in strongly coupled cardiac electro-mechanics simulations.

6. An analysis of deformation-dependent electromechanical coupling in the mouse heart.

Review 7. How computer simulations of the human heart can improve anti-arrhythmia therapy.

8. Computational modeling of chemo-electro-mechanical coupling: a novel implicit monolithic finite element approach.

9. Beta-adrenergic stimulation maintains cardiac function in Serca2 knockout mice.

Review 10. Hierarchical approaches for systems modeling in cardiac development.