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Analyzing the effect of electrode size on electrogram and activation map properties

Atrial electrograms recorded from the epicardium provide an important tool for studying the initiation, perpetuation, and treatment of AF. However, the properties of these electrograms depend largely on the properties of the electrode arrays that are used for recording these signals. In this study,...

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Published in:Computers in biology and medicine 2021-07, Vol.134, p.104467-104467, Article 104467
Main Authors: Abdi, Bahareh, van Schie, Mathijs S., Groot, Natasja M.S. de, Hendriks, Richard C.
Format: Article
Language:English
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Summary:Atrial electrograms recorded from the epicardium provide an important tool for studying the initiation, perpetuation, and treatment of AF. However, the properties of these electrograms depend largely on the properties of the electrode arrays that are used for recording these signals. In this study, we use the electrode's transfer function to model and analyze the effect of electrode size on the properties of measured electrograms. To do so, we use both simulated as well as clinical data. To simulate electrogram arrays we use a two-dimensional (2D) electrogram model as well as an action propagation model. For clinical data, however, we first estimate the trans-membrane current for a higher resolution 2D modeled cell grid and later use these values to interpolate and model electrograms with different electrode sizes. We simulate electrogram arrays for 2D tissues with 3 different levels of heterogeneity in the conduction and stimulation pattern to model the inhomogeneous wave propagation observed during atrial fibrillation. Four measures are used to characterize the properties of the simulated electrogram arrays of different electrode sizes. The results show that increasing the electrode size increases the error in LAT estimation and decreases the length of conduction block lines. Moreover, visual inspection also shows that the activation maps generated by larger electrodes are more homogeneous with a lower number of observed wavelets. The increase in electrode size also increases the low voltage areas in the tissue while decreasing the slopes and the number of detected deflections. The effect is more pronounced for a tissue with a higher level of heterogeneity in the conduction pattern. Similar conclusions hold for the measurements performed on clinical data. The electrode size affects the properties of recorded electrogram arrays which can respectively complicate our understanding of atrial fibrillation. This needs to be considered while performing any analysis on the electrograms or comparing the results of different electrogram arrays. •The electrode size affects the properties of recorded electrogram arrays which complicates our understanding of AF.•Increasing the electrode size increases the error in LAT estimation and decreases the length of conduction block lines.•The effect of electrode size is more pronounced for a tissue with a higher level of heterogeneity in the conduction pattern.•The electrode size effect needs to be considered while performing
ISSN:0010-4825
1879-0534
DOI:10.1016/j.compbiomed.2021.104467