Improved Performance of Bayesian Solutions for Inverse Electrocardiography Using Multiple Information Sources

The usual goal in inverse electrocardiography (ECG) is to reconstruct cardiac electrical sources from body surface potentials and a mathematical model that relates the sources to the measurements. Due to attenuation and smoothing that occurs in the thorax, the inverse ECG problem is ill-posed and im...

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Bibliographic Details
Published inIEEE transactions on biomedical engineering Vol. 53; no. 10; pp. 2024 - 2034
Main Authors Serinagaoglu, Y., Brooks, D.H., Macleod, R.S.
Format Journal Article
LanguageEnglish
Published United States IEEE 01.10.2006
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects
Action Potentials - physiology
Algorithms
Attenuation
Bayes Theorem
Bayesian analysis
Bayesian estimation
Bayesian methods
Body Surface Potential Mapping - methods
Catheters
Computational Biology - methods
Computer Simulation
Diagnosis, Computer-Assisted - methods
Electric variables measurement
Electrocardiography
Electrocardiography - methods
forward/inverse modeling
Heart
Heart Conduction System - physiopathology
Humans
inverse electrocardiography
inverse problems
Mathematical model
Mathematical models
Models, Cardiovascular
Smoothing methods
Studies
Surface reconstruction
Thorax
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Summary:The usual goal in inverse electrocardiography (ECG) is to reconstruct cardiac electrical sources from body surface potentials and a mathematical model that relates the sources to the measurements. Due to attenuation and smoothing that occurs in the thorax, the inverse ECG problem is ill-posed and imposition of a priori constraints is needed to combat this ill-posedness. When the problem is posed in terms of reconstructing heart surface potentials, solutions have not yet achieved clinical utility; limitations include the limited availability of good a priori information about the solution and the lack of a "good" error metric. We describe an approach that combines body surface measurements and standard forward models with two additional information sources: statistical prior information about epicardial potential distributions and sparse simultaneous measurements of epicardial potentials made with multielectrode coronary venous catheters. We employ a Bayesian methodology which offers a general way to incorporate these information sources and additionally provides statistical performance analysis tools. In a simulation study, we first compare solutions using one or more of these information sources. Then, we study the effects of varying the number of sparse epicardial potential measurements on reconstruction accuracy. To evaluate accuracy, we used the Bayesian error covariance as well as traditional error metrics such as relative error. Our results show that including even sparsely sampled information from coronary venous catheters can substantially improve the reconstruction of epicardial potential distributions and that a Bayesian framework provides a feasible approach to using this information. Moreover, computing the Bayesian error standard deviations offers a means to indicate confidence in the results even in the absence of validation data
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ISSN:0018-9294
1558-2531
DOI:10.1109/TBME.2006.881776