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The electrophysiological cardiac ventricular substrate in patients after myocardial infarction: noninvasive characterization with electrocardiographic imaging.心肌梗死后患者的电生理心室基质:心电图成象的无创特征。
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Cardiac position sensitivity study in the electrocardiographic forward problem using stochastic collocation and boundary element methods.使用随机配置和边界元方法进行心电图正问题中心位置敏感性研究。
Ann Biomed Eng. 2011 Dec;39(12):2900-10. doi: 10.1007/s10439-011-0391-5. Epub 2011 Sep 10.
5
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6
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7
Noninvasive computational imaging of cardiac electrophysiology for 3-D infarct.三维梗死的心脏电生理无创计算成像。
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8
On epicardial potential reconstruction using regularization schemes with the L1-norm data term.基于 L1-范数数据项的正则化方案进行心外膜电位重建。
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Noninvasive characterization of epicardial activation in humans with diverse atrial fibrillation patterns.用不同心房颤动模式的人类进行心外膜激活的无创特征描述。
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非侵入性心脏电生理成像对个性化解剖模型变化的敏感性。

Sensitivity of Noninvasive Cardiac Electrophysiological Imaging to Variations in Personalized Anatomical Modeling.

作者信息

Rahimi Azar

出版信息

IEEE Trans Biomed Eng. 2015 Jun;62(6):1563-75. doi: 10.1109/TBME.2015.2395387. Epub 2015 Jan 21.

DOI:10.1109/TBME.2015.2395387
PMID:25615906
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4581729/
Abstract

OBJECTIVE

Noninvasive cardiac electrophysiological (EP) imaging techniques rely on anatomically-detailed heart-torso models derived from high-quality tomographic images of individual subjects. However, anatomical modeling involves variations that lead to unresolved uncertainties in the outcome of EP imaging, bringing questions to the robustness of these methods in clinical practice. In this study, we design a systematic statistical approach to assess the sensitivity of EP imaging methods to the variations in personalized anatomical modeling.

METHODS

We first quantify the variations in personalized anatomical models by a novel application of statistical shape modeling. Given the statistical distribution of the variation in personalized anatomical models, we then employ unscented transform to determine the sensitivity of EP imaging outputs to the variation in input personalized anatomical modeling.

RESULTS

We test the feasibility of our proposed approach using two of the existing EP imaging methods: epicardial-based electrocardiographic imaging and transmural electrophysiological imaging. Both phantom and real-data experiments show that variations in personalized anatomical models have negligible impact on the outcome of EP imaging.

CONCLUSION

This study verifies the robustness of EP imaging methods to the errors in personalized anatomical modeling and suggests the possibility to simplify the process of anatomical modeling in future clinical practice.

SIGNIFICANCE

This study proposes a systematic statistical approach to quantify anatomical modeling variations and assess their impact on EP imaging, which can be extended to find a balance between the quality of personalized anatomical models and the accuracy of EP imaging that may improve the clinical feasibility of EP imaging.

摘要

目的

无创心脏电生理(EP)成像技术依赖于从个体受试者的高质量断层图像中获取的具有详细解剖结构的心脏-躯干模型。然而,解剖建模存在差异,导致EP成像结果存在未解决的不确定性,这使得这些方法在临床实践中的稳健性受到质疑。在本研究中,我们设计了一种系统的统计方法来评估EP成像方法对个性化解剖建模差异的敏感性。

方法

我们首先通过统计形状建模的一种新应用来量化个性化解剖模型中的差异。鉴于个性化解剖模型差异的统计分布,然后我们采用无迹变换来确定EP成像输出对输入个性化解剖建模差异的敏感性。

结果

我们使用两种现有的EP成像方法——基于心外膜的心电图成像和透壁电生理成像,测试了我们提出的方法的可行性。模型和真实数据实验均表明,个性化解剖模型的差异对EP成像结果的影响可忽略不计。

结论

本研究验证了EP成像方法对个性化解剖建模误差的稳健性,并表明在未来临床实践中简化解剖建模过程的可能性。

意义

本研究提出了一种系统的统计方法来量化解剖建模差异并评估其对EP成像的影响,该方法可扩展以在个性化解剖模型质量和EP成像准确性之间找到平衡,这可能会提高EP成像的临床可行性。