Cardiac Electromechanics and the Forward/Inverse Problems of Electrocardiology

Author

Buist, M.L. ; Smith, N.P. ; Pullan, A.J.

Author_Institution

Div. of Bioengineering, Nat. Univ. of Singapore

fYear

2006

Firstpage

7198

Lastpage

7200

Abstract

The mechanical motion of the heart plays a role in determining the waveforms observed in an ECG. This study is designed to ascertain, from a theoretical perspective, the influence of this motion. This is achieved through an analysis of a detailed forward model including a full bidomain description and a strongly coupled model of cardiac electromechanics. Simulations were run on identical problems with and without the inclusion of mechanical deformation and the results were analyzed with a view towards the inverse problem of electrocardiology. Initial results have shown the QRS complex to be largely invariant under deformation, but significant changes in T wave morphology have been observed. Further analysis has revealed that it is the effect of the cell-level mechanics on repolarization that is primarily responsible for these changes as opposed to the tissue deformation

Keywords

biomechanics; cellular biophysics; deformation; electrocardiography; inverse problems; QRS complex; T wave morphology; cardiac electromechanics; cell-level mechanics; electrocardiology; forward problem; heart mechanical motion; inverse problem; mechanical deformation; tissue deformation; Biomedical engineering; Conductivity; Elasticity; Equations; Extracellular; Finite element methods; Forward contracts; Inverse problems; Optical fiber theory; Torso;

fLanguage

English

Publisher

ieee

Conference_Titel

Engineering in Medicine and Biology Society, 2005. IEEE-EMBS 2005. 27th Annual International Conference of the

Conference_Location

Shanghai

Print_ISBN

0-7803-8741-4

Type

conf

DOI

10.1109/IEMBS.2005.1616169

Filename

1616169