Glenn Terje Lines
Cited by
Cited by
Computing the electrical activity in the heart
J Sundnes, GT Lines, X Cai, BF Nielsen, KA Mardal, A Tveito
Springer Science & Business Media, 2007
An operator splitting method for solving the bidomain equations coupled to a volume conductor model for the torso
J Sundnes, GT Lines, A Tveito
Mathematical biosciences 194 (2), 233-248, 2005
On the computational complexity of the bidomain and the monodomain models of electrophysiology
J Sundnes, BF Nielsen, KA Mardal, X Cai, GT Lines, A Tveito
Annals of biomedical engineering 34, 1088-1097, 2006
Mathematical models and numerical methods for the forward problem in cardiac electrophysiology
GT Lines, ML Buist, P Grottum, AJ Pullan, J Sundnes, A Tveito
Computing and Visualization in Science 5, 215-239, 2003
Ryanodine receptor dispersion disrupts Ca2+ release in failing cardiac myocytes
TR Kolstad, J van den Brink, N MacQuaide, PK Lunde, M Frisk, ...
Elife 7, e39427, 2018
Efficient solution of ordinary differential equations modeling electrical activity in cardiac cells
J Sundnes, GT Lines, A Tveito
Mathematical biosciences 172 (2), 55-72, 2001
Multigrid block preconditioning for a coupled system of partial differential equations modeling the electrical activity in the heart
J Sundnes, GT Lines, KA Mardal, A Tveito
Computer Methods in Biomechanics & Biomedical Engineering 5 (6), 397-409, 2002
Simulation of ST segment changes during subendocardial ischemia using a realistic 3-D cardiac geometry
MC MacLachlan, J Sundnes, GT Lines
IEEE Transactions on Biomedical Engineering 52 (5), 799-807, 2005
Modeling the electrical activity of the heart: a bidomain model of the ventricles embedded in a torso
GT Lines, P Grottum, A Tveito
Computing and Visualization in Science 5, 195-213, 2003
Contribution of the Na+/Ca2+ exchanger to rapid Ca2+ release in cardiomyocytes
GT Lines, JB Sande, WE Louch, HK Mørk, P Grøttum, OM Sejersted
Biophysical journal 91 (3), 779-792, 2006
An evaluation of the accuracy of classical models for computing the membrane potential and extracellular potential for neurons
A Tveito, KH Jæger, GT Lines, Ł Paszkowski, J Sundnes, AG Edwards, ...
Frontiers in computational neuroscience 11, 27, 2017
Numerical solution of the bidomain equations
S Linge, J Sundnes, M Hanslien, GT Lines, A Tveito
Philosophical Transactions of the Royal Society A: Mathematical, Physical …, 2009
Optimal monodomain approximations of the bidomain equations
BF Nielsen, TS Ruud, GT Lines, A Tveito
Applied Mathematics and Computation 184 (2), 276-290, 2007
Adaptive finite element simulation of ventricular fibrillation dynamics
P Deuflhard, B Erdmann, R Roitzsch, GT Lines
Computing and visualization in science 12 (5), 201-205, 2009
Control of Ca2+ release by action potential configuration in normal and failing murine cardiomyocytes
WE Louch, J Hake, GF Jølle, HK Mørk, I Sjaastad, GT Lines, OM Sejersted
Biophysical journal 99 (5), 1377-1386, 2010
AMICI: high-performance sensitivity analysis for large ordinary differential equation models
F Fröhlich, D Weindl, Y Schälte, D Pathirana, Ł Paszkowski, GT Lines, ...
Bioinformatics 37 (20), 3676-3677, 2021
Stochastic binding of Ca2+ ions in the dyadic cleft; continuous versus random walk description of diffusion
J Hake, GT Lines
Biophysical journal 94 (11), 4184-4201, 2008
A condition for setting off ectopic waves in computational models of excitable cells
A Tveito, GT Lines
Mathematical Biosciences 213 (2), 141-150, 2008
Mathematical models of cardiac pacemaking function
P Li, GT Lines, MM Maleckar, A Tveito
Frontiers in Physics 1, 20, 2013
Scalable heterogeneous CPU-GPU computations for unstructured tetrahedral meshes
J Langguth, M Sourouri, GT Lines, SB Baden, X Cai
IEEE Micro 35 (4), 6-15, 2015
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