A 3-D finite element cardiac model and its application to body surface Laplacian mapping

Author

Yin, J.Z. ; He, B. ; Cohen, R.J.

Author_Institution

Harvard Div. of Health Sci. & Technol., MIT, Cambridge, MA, USA

fYear

1992

Firstpage

247

Lastpage

250

Abstract

A new 3-D finite element model of cardiac electrical conduction has been developed. The purpose of this study was to construct a simple but physiologically reasonable heart model and to simulate body surface Laplacian maps (BSLMs). The heart model consists of 29,109 elements in a cubic lattice with left and right ventricular boundaries. Each element has three intrinsic states-resting, depolarizing, and refractory-and interacts with its neighbors by a weighted probability interaction rule. The BSLM is calculated directly from the current dipole distribution within the heart. The results of normal sequence and left/right bundle branch block simulations, closely matched the experimental results of B. He et al. (1992) and demonstrate the ability of BSLM to resolve and image normal and abnormal cardiac electrical activity with high spatial resolution

Keywords

cardiology; electrocardiography; finite element analysis; physiological models; 3D finite element cardiac model; body surface Laplacian mapping; bundle branch block simulations; cardiac electrical conduction; cubic lattice; current dipole distribution; depolarizing state; left ventricular boundary; physiologically reasonable heart model; refractory state; resting state; right ventricular boundary; spatial resolution; weighted probability interaction rule; Biological system modeling; Computational modeling; Finite element methods; Heart; Helium; Laplace equations; Lattices; Myocardium; Nearest neighbor searches; Spatial resolution;

fLanguage

English

Publisher

ieee

Conference_Titel

Computers in Cardiology 1992, Proceedings of

Conference_Location

Durham, NC

Print_ISBN

0-8186-3552-5

Type

conf

DOI

10.1109/CIC.1992.269400

Filename

269400