Transient Hemodynamics Prediction Using an Efficient Octree-Based Deep Learning Model

TL;DR

This paper introduces an octree-based deep learning model that efficiently predicts high-resolution transient hemodynamics in complex vascular geometries, significantly reducing computation time while maintaining accuracy.

Contribution

The novel architecture combines octree spatial discretization with neural functions to accurately predict 3D velocity fields in complex neurovascular simulations.

Findings

Velocity field prediction with mean absolute error of 0.024 m/s

Simulation time reduced from hours to seconds

Effective for cerebral hemodynamics during contrast injection

Abstract

Patient-specific hemodynamics assessment could support diagnosis and treatment of neurovascular diseases. Currently, conventional medical imaging modalities are not able to accurately acquire high-resolution hemodynamic information that would be required to assess complex neurovascular pathologies. Therefore, computational fluid dynamics (CFD) simulations can be applied to tomographic reconstructions to obtain clinically relevant information. However, three-dimensional (3D) CFD simulations require enormous computational resources and simulation-related expert knowledge that are usually not available in clinical environments. Recently, deep-learning-based methods have been proposed as CFD surrogates to improve computational efficiency. Nevertheless, the prediction of high-resolution transient CFD simulations for complex vascular geometries poses a challenge to conventional deep learning models. In this work, we present an architecture that is tailored to predict high-resolution (spatial and temporal) velocity fields for complex synthetic vascular geometries. For this, an octree-based spatial discretization is combined with an implicit neural function representation to efficiently handle the prediction of the 3D velocity field for each time step. The presented method is evaluated for the task of cerebral hemodynamics prediction before and during the injection of contrast agent in the internal carotid artery (ICA). Compared to CFD simulations, the velocity field can be estimated with a mean absolute error of 0.024 m/s, whereas the run time reduces from several hours on a high-performance cluster to a few seconds on a consumer graphical processing unit.