TY - GEN
T1 - Assessing influence of conductivity in heart modelling with the aim of studying cardiovascular diseases
AU - Sebastian, Rafael
AU - Ordas, Sebastian
AU - Plank, Gernot
AU - Rodriguez, Blanca
AU - Vigmond, Edward J.
AU - Frangi, Alejandro F.
PY - 2008
Y1 - 2008
N2 - The bidomain/monodomain equations have been widely used to model electrical activity in cardiac tissue. Here we present a sensitivity study of a crucial parameter in the bidomain model, the tissue conductivity. This study is necessary since there is no general agreement on the actual values that should be employed, mainly due to inconsistencies between the few sources of empirical information existent in the literature. Furthermore, estimates of this parameter from either imaging techniques or from experiments on isolated cardiac tissue have been inconsistent. For this study, a 3D biventricular model built from Multi-Detector Computer Tomography was used with the most relevant electrical structures, such as myocardial fiber orientation and the Purkinje system, were included. Specific ionic models for normal myocardium and for the Purkinje system were taken into account. Finite Element methods were used to solve the monodomain equation for a number of different conductivity settings. Comparative results using isochronal maps are shown in combination with statistical tests to measure changes in the sequence of electrical activation in the myocardium, conduction velocities (CV), and local activation times (LAT).
AB - The bidomain/monodomain equations have been widely used to model electrical activity in cardiac tissue. Here we present a sensitivity study of a crucial parameter in the bidomain model, the tissue conductivity. This study is necessary since there is no general agreement on the actual values that should be employed, mainly due to inconsistencies between the few sources of empirical information existent in the literature. Furthermore, estimates of this parameter from either imaging techniques or from experiments on isolated cardiac tissue have been inconsistent. For this study, a 3D biventricular model built from Multi-Detector Computer Tomography was used with the most relevant electrical structures, such as myocardial fiber orientation and the Purkinje system, were included. Specific ionic models for normal myocardium and for the Purkinje system were taken into account. Finite Element methods were used to solve the monodomain equation for a number of different conductivity settings. Comparative results using isochronal maps are shown in combination with statistical tests to measure changes in the sequence of electrical activation in the myocardium, conduction velocities (CV), and local activation times (LAT).
KW - Cardiac electrical modelling
KW - Cardiac tissue
KW - Conductivity
KW - FEM simulation
KW - Patient-specific geometry model
UR - http://www.scopus.com/inward/record.url?scp=44349175375&partnerID=8YFLogxK
U2 - 10.1117/12.770258
DO - 10.1117/12.770258
M3 - Conference contribution
AN - SCOPUS:44349175375
SN - 9780819471000
T3 - Progress in Biomedical Optics and Imaging - Proceedings of SPIE
BT - Medical Imaging 2008 - Physiology, Function, and Structure from Medical Images
T2 - Medical Imaging 2008 - Physiology, Function, and Structure from Medical Images
Y2 - 17 February 2008 through 19 February 2008
ER -
