Litcius/Paper detail

Uncovering near-wall blood flow from sparse data with physics-informed neural networks

Amirhossein Arzani, Jian-Xun Wang, Roshan M. D'Souza

2021Physics of Fluids247 citationsDOIOpen Access PDF

Abstract

Near-wall blood flow and wall shear stress (WSS) regulate major forms of cardiovascular disease, yet they are challenging to quantify with high fidelity. Patient-specific computational and experimental measurement of WSS suffers from uncertainty, low resolution, and noise issues. Physics-informed neural networks (PINNs) provide a flexible deep learning framework to integrate mathematical equations governing blood flow with measurement data. By leveraging knowledge about the governing equations (herein, Navier–Stokes), PINN overcomes the large data requirement in deep learning. In this study, it was shown how PINN could be used to improve WSS quantification in diseased arterial flows. Specifically, blood flow problems where the inlet and outlet boundary conditions were not known were solved by assimilating very few measurement points. Uncertainty in boundary conditions is a common feature in patient-specific computational fluid dynamics models. It was shown that PINN could use sparse velocity measurements away from the wall to quantify WSS with very high accuracy even without full knowledge of the boundary conditions. Examples in idealized stenosis and aneurysm models were considered demonstrating how partial knowledge about the flow physics could be combined with partial measurements to obtain accurate near-wall blood flow data. The proposed hybrid data-driven and physics-based deep learning framework has high potential in transforming high-fidelity near-wall hemodynamics modeling in cardiovascular disease.

Topics & Concepts

Flow (mathematics)Blood flowArtificial intelligencePhysicsBoundary (topology)Artificial neural networkDeep learningBoundary value problemFeature (linguistics)Partial differential equationNoise (video)AlgorithmPattern recognition (psychology)Computer scienceFluid dynamicsRepresentation (politics)Noise reductionUncertainty quantificationComputational fluid dynamicsSparse approximationHemodynamicsApplied mathematicsFeature extractionNavier–Stokes equationsMechanicsReduction (mathematics)Sparse matrixPrincipal component analysisComputational modelMachine learningFluid mechanicsShear stressData modelingMultiscale modelingFluid–structure interactionModel Reduction and Neural NetworksCoronary Interventions and DiagnosticsElasticity and Material Modeling