A SIMULATION STUDY ON MAGNETIC SOURCE IMAGING WITH A REALISTIC MODEL OF THE ENTIRE HUMAN HEART

A computer model study on magnetic source imaging from magnetocardiogr aphic data is presented using a cellular automaton model of the entire human heart in the so-called forward problem. A homogeneous boundary element (BE) torso is built up from real magnetic resonance imaging (M RI) cross-sections. The heart model, which has a realistic anatomical shape, is positioned inside the BE torso. in the forward problem the s pread of excitation is simulated by applying a modified Huygen's propa gation principle. The magnetocardiogram (MCG) and electrocardiogram (E GG) can then be computed following the bidomain theory. From the simul ated MCG data, pseudo primary current dipole (PPCD) estimation within the electrically active tissue is performed. The reconstruction space is defined as a surface in the middle of the atrial and ventricular my ocardium and septum. The observation space consists of two mutually pe rpendicular planes closely above the torso surface on the frontal and the left lateral side, respectively. An iterative minimum-norm approac h is applied in order to reconstruct PPCD distributions. The errors in PPCD estimation arising from noisy data and regularization algorithms are investigated in more detail.