Title :
A parallelizable technique for 3D simulations of cardiac electrical propagation based on sub-cellular physiology
Author :
Pergola, Nicholas F. ; Buchanan, Jack W.
Author_Institution :
Dept. of Biomed. Eng., Tennessee Univ., Memphis, TN, USA
Abstract :
A new methodology was developed for numerical simulations of cardiac electrical activity. The technique allows larger and more complex models to be examined while retaining sub-cellular resolution and physiology. The cable model of cardiac tissue assumes a network of passive resistances linking ionic and capacitive membrane elements. This model was adapted for implementation in high performance parallel and vector computing environments. The methods were then expanded to allow for modeling of three dimensional geometries. Preliminary simulations show qualitative agreement with the authors´ previous studies, providing validation of the revised techniques
Keywords :
bioelectric phenomena; biology computing; cardiology; cellular biophysics; numerical analysis; parallel processing; physiological models; 3D simulations; cable model; capacitive membrane elements; cardiac electrical propagation; cardiac tissue; complex models; ionic membrane elements; parallelizable technique; passive resistances network; subcellular physiology; vector computing; Biomembranes; Cardiac tissue; Computational modeling; Concurrent computing; Geometry; High performance computing; Joining processes; Numerical simulation; Physiology; Solid modeling;
Conference_Titel :
Computers in Cardiology, 1996
Conference_Location :
Indianapolis, IN
Print_ISBN :
0-7803-3710-7
DOI :
10.1109/CIC.1996.542612
