Litcius/Paper detail

Whole-heart electromechanical simulations using Latent Neural Ordinary Differential Equations

Matteo Salvador, Marina Strocchi, Francesco Regazzoni, Christoph M. Augustin, Luca Dede’, Steven Niederer, Alfio Quarteroni

2024npj Digital Medicine37 citationsDOIOpen Access PDF

Abstract

Cardiac digital twins provide a physics and physiology informed framework to deliver personalized medicine. However, high-fidelity multi-scale cardiac models remain a barrier to adoption due to their extensive computational costs. Artificial Intelligence-based methods can make the creation of fast and accurate whole-heart digital twins feasible. We use Latent Neural Ordinary Differential Equations (LNODEs) to learn the pressure-volume dynamics of a heart failure patient. Our surrogate model is trained from 400 simulations while accounting for 43 parameters describing cell-to-organ cardiac electromechanics and cardiovascular hemodynamics. LNODEs provide a compact representation of the 3D-0D model in a latent space by means of an Artificial Neural Network that retains only 3 hidden layers with 13 neurons per layer and allows for numerical simulations of cardiac function on a single processor. We employ LNODEs to perform global sensitivity analysis and parameter estimation with uncertainty quantification in 3 hours of computations, still on a single processor.

Topics & Concepts

Artificial neural networkComputer scienceOrdinary differential equationArtificial intelligenceSensitivity (control systems)Automatic differentiationComputationSurrogate modelMachine learningDifferential equationAlgorithmMathematicsEngineeringElectronic engineeringMathematical analysisCardiac electrophysiology and arrhythmiasCardiovascular Function and Risk FactorsModel Reduction and Neural Networks