Spatiotemporal approximation of cardiac activation and recovery isochrones

Spatiotemporal approximation of cardiac activation and recovery isochrones

The sequence of myocardial activation and recovery can be studied in detail by invasive catheter recordings of cardiac electrograms (EGMs), or noninvasive inverse reconstructions thereof with electrocardiographic imaging (ECGI). Local activation and recovery times are obtained from a unipolar EGM by...

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Published in:Journal of electrocardiology Vol. 71; pp. 1 - 9
Main Authors: Cluitmans, Matthijs, Coll-Font, Jaume, Erem, Burak, Bear, Laura, Nguyên, Uyên Châu, ter Bekke, Rachel, Volders, Paul G.A., Brooks, Dana
Format: Journal Article
Language:English
Published: United States Elsevier Inc 01-03-2022
Elsevier Science Ltd
Subjects:
Activation time
Animals
Arrhythmias, Cardiac - diagnosis
Body Surface Potential Mapping - methods
Cardiac arrhythmia
Cardiovascular disease
Electrocardiography
Electrocardiography - methods
Electrophysiologic Techniques, Cardiac
Heart - diagnostic imaging
Heart attacks
Humans
Medical imaging
Recovery time
Signal processing
Unipolar electrograms
Signal processing
Activation time
Recovery time
Unipolar electrograms
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Summary:The sequence of myocardial activation and recovery can be studied in detail by invasive catheter recordings of cardiac electrograms (EGMs), or noninvasive inverse reconstructions thereof with electrocardiographic imaging (ECGI). Local activation and recovery times are obtained from a unipolar EGM by the moment of maximum downslope of the QRS complex or maximum upslope of the T wave, respectively. However, both invasive and noninvasive recordings of intracardiac EGMs may suffer from noise and fractionation, making reliable detection of these deflections nontrivial. Here, we introduce a novel method that benefits from the spatial coupling of these processes, and incorporate not only the temporal EGM deflection, but also the spatial gradients. We validated this approach in computer simulations, in animal data with ECGI and invasive electrode recordings, and illustrated its use in a clinical case. In the simulated data, the spatiotemporal approach was able to incorporate spatial information to better select the correct deflection in artificially fractionated EGMs and outperformed the traditional temporal-only method. In experimental data, the accuracy of time estimation from ECGI compared to invasive recordings significantly increased from R = 0.73 (activation) and R = 0.58 (recovery) with the temporal-only method to R = 0.79 (activation) and R = 0.72 (recovery) with the novel approach. Localization of the pacing origin of paced beats improved significantly from 36 mm mean error with the temporal-only approach to 23 mm with the spatiotemporal approach. The spatiotemporal method to compute activation and recovery times from EGMs outperformed the traditional temporal-only approach in which spatial information was not taken into account. •Cardiac electrograms are routinely used to study activation and recovery sequence.•They may contain noise, making it difficult to determine the deflection time.•The processes are spatially coupled and result in a temporal and spatial deflection.•Such a spatiotemporal activation and recovery time computation is more accurate.•This benefits invasive catheter procedures and noninvasive electrocardiographic imaging.
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ISSN:0022-0736
1532-8430
DOI:10.1016/j.jelectrocard.2021.12.007