Reduced leadset selection and performance evaluation in the inverse problem of electrocardiography for reconstructing the ventricularly paced electrograms.

OBJECTIVE: Noninvasive electrocardiographic imaging (ECGI) is used for obtaining high-resolution images of the electrical activity of the heart, and is a powerful method with the potential to detect certain arrhythmias. However, there is no 'best' lead configuration in the literature to measure the torso potentials. This paper evaluates ECGI reconstructions using various reduced leadset configurations, explores whether one can find a common reduced leadset configuration that can accurately reconstruct the electrograms for datasets with different pacing sites, and compares two activation time estimation methods. APPROACH: We used 23 ventricularly-paced datasets with pacing sites on different regions of the epicardium. Starting with a full 192­leadset, we found "optimized" reduced leadsets specific to each dataset; we considered 64­lead and 32­lead configurations. Based on the histogram of individual "optimized" lead selections, we found a common reduced leadset. We compared the ECGI reconstructions and activation times of the individually optimized lead configurations with the common lead configurations. RESULTS: Both 64­lead configurations had similar performances to the 192­leadset. 32­leadset configurations, on the other hand, yielded noisy reconstructions, which affected their performance. SIGNIFICANCE: There are no statistically significant differences in the performance of the inverse solutions when a 64­lead common reduced leadset is used to estimate the electrograms and their respective pacing sites compared to using the full leadset. 32­lead configurations, on the other hand, require a more careful study to improve their performance. The activation time method used significantly affects the pacing site estimation performance, especially with fewer electrodes.