Abstract
In recent years, computational fluid dynamics (CFD) has become a valuable tool for investigating hemodynamics in cerebral aneurysms. CFD provides flow-related quantities, which have been shown to have a potential impact on aneurysm growth and risk of rupture. However, the adoption of CFD tools in clinical settings is currently limited by the high computational cost and the engineering expertise required for employing these tools, e.g., for mesh generation, appropriate choice of spatial and temporal resolution, and of boundary conditions. Herein, we address these challenges by introducing a practical and robust methodology, focusing on computational performance and minimizing user interaction through automated parameter selection. We propose a fully automated pipeline that covers the steps from a patient-specific anatomical model to results, based on a fast, graphics processing unit- (GPU-) accelerated CFD solver and a parameter selection methodology. We use a reduced order model to compute the initial estimates of the spatial and temporal resolutions and an iterative approach that further adjusts the resolution during the simulation without user interaction. The pipeline and the solver are validated based on previously published results, and by comparing the results obtained for 20 cerebral aneurysm cases with those generated by a state-of-the-art commercial solver (Ansys CFX, Canonsburg PA). The automatically selected spatial and temporal resolutions lead to results which closely agree with the state-of-the-art, with an average relative difference of only 2%. Due to the GPU-based parallelization, simulations are computationally efficient, with a median computation time of 40 minutes per simulation.
Highlights
Intracranial aneurysms are pathological disorders which consist of an abnormal dilatation of the vessel wall
The numerical implementation of the lattice Boltzmann method was extensively validated in the past on analytical cases with known results, e.g., Womersley flow and channel flow [41, 60]
We proposed a workflow aimed at improving the potential of using computational fluid dynamics (CFD)-based tools in a clinical setting, as a tool for aiding decision making and establishing a personalized treatment plan for cerebral aneurysms
Summary
Intracranial aneurysms are pathological disorders which consist of an abnormal dilatation of the vessel wall. The incidence of unruptured aneurysms is high as it occurs in about 6% of the population; the rupture incidence is very low, 7.7 in 100000 cases annually [2]. The treatment of unruptured aneurysms has a high economic cost [3]. Due to its high incidence, it is critical to accurately identify the subset of patients with high risk of rupture and plan the treatment . One possibility is to surgically clip the aneurysm at its neck, to isolate the aneurysmal dome, and to prevent bleeding [4]. Another solution consists of filling the aneurysm with thin wires that constrict the flow
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