Noninvasive epicardial and endocardial electrocardiographic imaging of scar-related ventricular tachycardia

Wang, Linwei; Gharbia, Omar A.; Horáček, B. Milan; Sapp, John L.

doi:10.1016/j.jelectrocard.2016.07.026

Cited by 29 publications

(24 citation statements)

References 21 publications

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“…The work by Li and He [12] solves this inverse problem by means of heart-model parameters (onset activation location) and was further extended [13] and validated on rabbits [14] and swines [15], [16]. More recently, [17] was able to reconstruct re-entry circuits to correctly reveal both epicardial and endocardial origins of activation, consistent with locations of exit sites confirmed from the ablation procedure. Nevertheless, while it is useful in capturing and analysing global activation patterns, it still has limitations to assess the local abnormal ventricular activities (LAVA) like those studied here which serve as ablation targets for cardiac arrhythmia treatment.…”

Section: Introductionmentioning

confidence: 92%

Model-Based Feature Augmentation for Cardiac Ablation Target Learning From Images

Lozoya

Berte

Cochet

et al. 2019

IEEE Trans. Biomed. Eng.

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Abstract-Goal: We present a model-based feature augmentation scheme to improve the performance of a learning algorithm for the detection of cardiac radio-frequency ablation (RFA) targets with respect to learning from images alone. Methods: Initially, we compute image features from delayed-enhanced MRI (DE-MRI) to describe local tissue heterogeneities and feed them into a machine learning framework with uncertainty assessment for the identification of potential ablation targets. Next, we introduce the use of a patient-specific image-based model derived from DE-MRI coupled with the Mitchell-Schaeffer electrophysiology model and a dipole formulation for the simulation of intracardiac electrograms (EGM). Relevant features are extracted from these simulated signals which serve as a feature augmentation scheme for the learning algorithm. We assess the classifier's performance when using only image features and with model-based feature augmentation. Results: We obtained average classification scores of 97.2% accuracy, 82.4% sensitivity and 95.0% positive predictive value (PPV) by using a model-based feature augmentation scheme. Preliminary results also show that training the algorithm on the closest patient from the database, instead of using all the patients, improves the classification results. Conclusion: We presented a feature augmentation scheme based on biophysical cardiac electrophysiology modeling to increase the prediction scores of a machine learning framework for the RFA target prediction. Significance: The results derived from this study are a proof of concept that the use of model-based feature augmentation strengthens the performance of a purely image driven learning scheme for the prediction of cardiac ablation targets.

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Section: Introductionmentioning

confidence: 92%

Model-Based Feature Augmentation for Cardiac Ablation Target Learning From Images

Lozoya

Berte

Cochet

et al. 2019

IEEE Trans. Biomed. Eng.

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“…Several studies have validated the use of ECGi mapping for catheter ablation in patients with PVC/VT. 21 , 50 , 59 , 63 The localization of the VT and PVC pacing sites by non-invasive electrophysiological mapping using 120 21 , 59 , 63 or up to 208 body surface electrodes 50 prior to the invasive procedure was shown to be correlated with the results from the invasive mapping system CARTO.…”

Section: Ventricular Arrhythmiasmentioning

confidence: 98%

Electrocardiographic imaging for cardiac arrhythmias and resynchronization therapy

2020

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Use of the 12-lead electrocardiogram (ECG) is fundamental for the assessment of heart disease, including arrhythmias, but cannot always reveal the underlying mechanism or the location of the arrhythmia origin. Electrocardiographic imaging (ECGi) is a non-invasive multi-lead ECG-type imaging tool that enhances conventional 12-lead ECG. Although it is an established technology, its continuous development has been shown to assist in arrhythmic activation mapping and provide insights into the mechanism of cardiac resynchronization therapy (CRT). This review addresses the validity, reliability, and overall feasibility of ECGi for use in a diverse range of arrhythmias. A systematic search limited to full-text human studies published in peer-reviewed journals was performed through Medline via PubMed, using various combinations of three key concepts: ECGi, arrhythmia, and CRT. A total of 456 studies were screened through titles and abstracts. Ultimately, 42 studies were included for literature review. Evidence to date suggests that ECGi can be used to provide diagnostic insights regarding the mechanistic basis of arrhythmias and the location of arrhythmia origin. Furthermore, ECGi can yield valuable information to guide therapeutic decision-making, including during CRT. Several studies have used ECGi as a diagnostic tool for atrial and ventricular arrhythmias. More recently, studies have tested the value of this technique in predicting outcomes of CRT. As a non-invasive method for assessing cardiovascular disease, particularly arrhythmias, ECGi represents a significant advancement over standard procedures in contemporary cardiology. Its full potential has yet to be fully explored.

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“…Assessment of deeper tissue characteristics may be enhanced with the addition of unipolar signal amplitude . Epicardial, intramyocardial, and ECG imaging recordings have demonstrated the potential 3D complexity of reentry circuits, which may pass deep to endocardial contact catheters.…”

Section: Chapter 2: Principles Of 3d Mappingmentioning

confidence: 99%

2019 APHRS expert consensus statement on three‐dimensional mapping systems for tachycardia developed in collaboration with HRS, EHRA, and LAHRS

Kim

Chen

Ernst

et al. 2020

Journal of Arrhythmia

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Noninvasive epicardial and endocardial electrocardiographic imaging of scar-related ventricular tachycardia

Cited by 29 publications

References 21 publications

Model-Based Feature Augmentation for Cardiac Ablation Target Learning From Images

Model-Based Feature Augmentation for Cardiac Ablation Target Learning From Images

Electrocardiographic imaging for cardiac arrhythmias and resynchronization therapy

2019 APHRS expert consensus statement on three‐dimensional mapping systems for tachycardia developed in collaboration with HRS, EHRA, and LAHRS

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