Ex Vivo Noninvasive Electrophysiologic Imaging Based on Cardiac Electrophysiology Simulation and Clinical Data

Abstract

Abstract Background: The risk stratification and prognosis of cardiac arrhythmia depend on the individual condition of patients, while invasive diagnostic methods may be risky to patient health, and current non-invasive diagnostic methods are applicable to few disease types without sensitivity and specificity. Cardiac electrophysiologic imaging technology reflects cardiac activities accurately and non-invasively, which is of great significance for the diagnosis and treatment of cardiac diseases. Methods: A complete three-dimensional bidomain cardiac electrophysiologic activity model was constructed, and simulated electrocardiogram data were obtained as training samples. Particle swarm optimization-back propagation neural network, convolutional neural network, and long short-term memory network were used respectively to reconstruct the cardiac surface potential. Results: The conduction sequence of simulation model is basically consistent with that of human heart. The P waves, PR intervals, QRS complex, and T waves in the simulated waveforms were within the normal clinical range, and the distribution trend of the simulated body surface potential mapping was consistent with the clinical data. The coefficient of determination R2 between the reconstruction results of all the algorithms and the true value is above 0.73, and the mean absolute error is below 14 mV, among which the R2 of long short-term memory network is about 0.97 and the mean absolute error about 1.2 mV. Conclusions: The electrophysiologic model constructed in this study can reflect the cardiac electrical activity, and basically contains the mapping relationship between the cardiac potential and the body surface potential. In cardiac potential reconstruction, long short-term memory network has significant advantages over other algorithms.