Identifying model inaccuracies and solution uncertainties in noninvasive activation-based imaging of cardiac excitation using convex relaxation
Publication year
2014Source
IEEE Transactions on Medical Imaging, 33, 4, (2014), pp. 902-12ISSN
Publication type
Article / Letter to editor
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Organization
Cognitive Neuroscience
Journal title
IEEE Transactions on Medical Imaging
Volume
vol. 33
Issue
iss. 4
Page start
p. 902
Page end
p. 12
Subject
Radboudumc 0: Other Research DCMN: Donders Center for Medical NeuroscienceAbstract
Noninvasive imaging of cardiac electrical function has begun to move towards clinical adoption. Here, we consider one common formulation of the problem, in which the goal is to estimate the spatial distribution of electrical activation times during a cardiac cycle. We address the challenge of understanding the robustness and uncertainty of solutions to this formulation. This formulation poses a nonconvex, nonlinear least squares optimization problem. We show that it can be relaxed to be convex, at the cost of some degree of physiological realism of the solution set, and that this relaxation can be used as a framework to study model inaccuracy and solution uncertainty. We present two examples, one using data from a healthy human subject and the other synthesized with the ECGSIM software package. In the first case, we consider uncertainty in the initial guess and regularization parameter. In the second case, we mimic the presence of an ischemic zone in the heart in a way which violates a model assumption. We show that the convex relaxation allows understanding of spatial distribution of parameter sensitivity in the first case, and identification of model violation in the second.
This item appears in the following Collection(s)
- Academic publications [242560]
- Faculty of Medical Sciences [92283]
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