A 3D/1D geometrical multiscale model of cerebral vasculature
Code:
12/2008
Title:
A 3D/1D geometrical multiscale model of cerebral vasculature
Date:
Thursday 26th June 2008
Author(s):
Passerini, Tiziano; de Luca, Maria Rita; Formaggia, Luca; Quarteroni, Alfio; Veneziani, Alessandro
Abstract:
Geometrical multiscale modeling is a strategy advocated in computational
hemodynamics for representing in a single numerical model dynamics that
involve different space scales. This approach is particularly useful to describe complex
networks such as the circle of Willis in the cerebral vasculature. In this paper
we present a multiscale model of the cerebral circulation where a one dimensional
description of the circle of Willis, relying on the one-dimensional Euler equations, is
coupled to a fully three dimensional model of a carotid artery, based on the solution
of the incompressible Navier-Stokes equations. Even if vascular compliance is often
not relevant to the meaningfulness of 3D results, it is crucial in the multiscale model,
since it is the driving mechanism of pressure wave propagation. Unfortunately, 3D
simulations in compliant domains still demand computational costs significantly
higher than the rigid case. Appropriate matching conditions between the two models
have been devised to concentrate the effects of the compliance at the interfaces and
to obtain reliable results still solving a 3D problems on rigid vessels