Title :
An efficient coupled electromechanical solver for studying human re-entrant arrhythmias
Author :
Kirk, Nathan ; Benson, Alan P. ; Hubbard, Matthew ; Goodyer, Christopher
Author_Institution :
Sch. of Comput., Univ. of Leeds, Leeds, UK
Abstract :
The study of cardiac arrhythmias is a major focus of computational biology, and undertaking biophysically detailed simulations is computationally demanding. An efficient coupled electromechanical solver to model cardiac tissue has been developed. This provides features to model fibre direction, and utilises computationally efficient techniques to reduce the simulation times. In this paper the break up of human re-entrant arrhythmias has been simulated. The results suggest that tissue deformation is a contributory factor in the break up of stable re-entrant spiral waves.
Keywords :
biological tissues; biology computing; cardiology; cardiac arrhythmias; cardiac tissue; computational biology; electromechanical solver; fibre direction model; human re-entrant arrhythmia; simulation times; stable reentrant spiral waves; tissue deformation; Biological system modeling; Computational modeling; Deformable models; Mathematical model; Spirals; Strain; Tensile stress;
Conference_Titel :
Computing in Cardiology, 2011
Conference_Location :
Hangzhou
Print_ISBN :
978-1-4577-0612-7
