Related papers: Deep Computational Model for the Inference of Ventricular Activation Properties

Deep Computational Model for the Inference of Ventricular Activation Properties

URL: http://arxiv.org/abs/2208.04028v1
Date: Mon, 8 Aug 2022 10:23:43 GMT
Title: Deep Computational Model for the Inference of Ventricular Activation Properties
Authors: Lei Li, Julia Camps, Abhirup Banerjee, Marcel Beetz, Blanca Rodriguez, Vicente Grau
Abstract summary: Patient-specific cardiac computational models are essential for the efficient realization of precision medicine and in-silico clinical trials using digital twins. We propose a deep learning based patient-specific computational model, which can fuse both anatomical and electrophysiological information for the inference of ventricular activation properties. We employ the Eikonal model to generate simulated electrocardiogram with ground truth properties to train the inference model, where specific patient information has also been considered.
Score: 10.886815576856574
License: http://creativecommons.org/licenses/by/4.0/
Abstract: Patient-specific cardiac computational models are essential for the efficient realization of precision medicine and in-silico clinical trials using digital twins. Cardiac digital twins can provide non-invasive characterizations of cardiac functions for individual patients, and therefore are promising for the patient-specific diagnosis and therapy stratification. However, current workflows for both the anatomical and functional twinning phases, referring to the inference of model anatomy and parameter from clinical data, are not sufficiently efficient, robust, and accurate. In this work, we propose a deep learning based patient-specific computational model, which can fuse both anatomical and electrophysiological information for the inference of ventricular activation properties, i.e., conduction velocities and root nodes. The activation properties can provide a quantitative assessment of cardiac electrophysiological function for the guidance of interventional procedures. We employ the Eikonal model to generate simulated electrocardiogram (ECG) with ground truth properties to train the inference model, where specific patient information has also been considered. For evaluation, we test the model on the simulated data and obtain generally promising results with fast computational time.

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