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Differential Equations for Studies in Computational Electrophysiology. Simula SpringerBriefs on Computing: Springer, 2023.
Nano-scale solution of the Poisson-Nernst-Planck (PNP) equations in a fraction of two neighboring cells reveals the magnitude of intercellular electrochemical waves." PLoS Computational Biology 19, no. 2 (2023): e1010895.
"Arrhythmogenic influence of mutations in a myocyte‑based computational model of the pulmonary vein sleeve." Nature Scientific Reports 12 (2022): 7040.
"Deriving the Bidomain Model of Cardiac Electrophysiology From a Cell-Based Model; Properties and Comparisons." Frontiers in Physiology 12 (2022): 811029.
"Metabolically driven maturation of human-induced-pluripotent-stem-cell-derived cardiac microtissues on microfluidic chips." Nature Biomedical Engineering 6, no. 4 (2022): 372-388.
"Validating the Arrhythmogenic Potential of High-, Intermediate-, and Low-Risk Drugs in a Human-Induced Pluripotent Stem Cell-Derived Cardiac Microphysiological System." ACS Pharmacology & Translational Science 5, no. 8 (2022): 652-667.
"A cell-based model for ionic electrodiffusion in excitable tissue." In Modeling Excitable Tissue: The EMI Framework, edited by K. Mardal, M. E. Rognes and A. Tveito, 14-27. Cham: Springer International Publishing, 2021.
"A computational method for identifying an optimal combination of existing drugs to repair the action potentials of SQT1 ventricular myocytes." PLoS Computational Biology 17 (2021): e1009233.
"Computational prediction of drug response in short QT syndrome type 1 based on measurements of compound effect in stem cell-derived cardiomyocytes." PLoS Computational Biology 17, no. 2 (2021): e1008089.
"Derivation of a Cell-Based Mathematical Model of Excitable Cells." In Modeling Excitable Tissue: The EMI Framework, edited by A. Tveito, K. Mardal and M. E. Rognes, 1-13. Vol. 7. Cham: Springer International Publishing, 2021.
"Derivation of a Cell-Based Mathematical Model of Excitable Cells." In Modeling Excitable Tissue: The EMI Framework, edited by A. Tveito, K. Mardal and M. E. Rognes, 1-13. Vol. 7. Cham: Springer International Publishing, 2021.
"Efficient numerical solution of the EMI model representing the extracellular space (E), cell membrane (M) and intracellular space (I) of a collection of cardiac cells." Frontiers in Physics 8 (2021): 579461.
"From Millimeters to Micrometers; Re-introducing Myocytes in Models of Cardiac Electrophysiology." Frontiers in Physiology 12 (2021): 763584.
"Identifying drug response by combining measurements of the membrane potential, the cytosolic calcium concentration, and the extracellular potential in microphysiological systems." Frontiers in Pharmacology 11 (2021): 569489.
"Improving Neural Simulations with the EMI Model." In Modeling Excitable Tissue: The EMI Framework, edited by A. Tveito, K. Mardal and M. E. Rognes, 87-98. Cham: Springer International Publishing, 2021.
"Iterative Solvers for EMI Models." In Modeling Excitable Tissue: The EMI Framework, edited by A. Tveito, K. Mardal and M. E. Rognes, 70-86. Cham: Springer International Publishing, 2021.
"Modeling Cardiac Mechanics on a Sub-Cellular Scale." In Modeling Excitable Tissue: The EMI Framework, edited by A. Tveito, M. E. Rognes and K. Mardal, 28-43. Vol. 7. Cham: Springer International Publishing, 2021.
telle2021_chapter_modelingcardiacmechanicsonasub.pdf (1.72 MB)
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Modeling Excitable Tissue: The EMI Framework, Edited by A. Tveito, K. Mardal and M. E. Rognes. Springer, 2021.
Operator Splitting and Finite Difference Schemes for Solving the EMI Model." In Modeling Excitable Tissue: The EMI Framework, edited by A. Tveito, K. Mardal and M. E. Rognes, 44-55. Vol. 7. Cham: Springer International Publishing, 2021.
"Operator Splitting and Finite Difference Schemes for Solving the EMI Model." In Modeling Excitable Tissue: The EMI Framework, edited by A. Tveito, K. Mardal and M. E. Rognes, 44-55. Vol. 7. Cham: Springer International Publishing, 2021.
"Solving the EMI Equations using Finite Element Methods." In Modeling Excitable Tissue: The EMI Framework, edited by A. Tveito, K. Mardal and M. E. Rognes, 56-69. Cham: Springer International Publishing, 2021.
"Computational translation of drug effects from animal experiments to human ventricular myocytes." Nature Scientific Reports (2020): 10537.
"Improved computational identification of drug response using optical measurements of human stem cell derived cardiomyocytes in microphysiological systems." Frontiers in Pharmacology 10 (2020).
"Detecting undetectables: Can conductances of action potential models be changed without appreciable change in the transmembrane potential?" Chaos 29 (2019).
"Finite element modeling of cardiac tissue in heart-on-a-chip systems In Washington DC, USA., 2019.