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Autori principali: Gjerde, Ingeborg G., Kuchta, Miroslav, Rognes, Marie E., Wohlmuth, Barbara
Natura: Preprint
Pubblicazione: 2023
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Accesso online:https://arxiv.org/abs/2401.00484
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author Gjerde, Ingeborg G.
Kuchta, Miroslav
Rognes, Marie E.
Wohlmuth, Barbara
author_facet Gjerde, Ingeborg G.
Kuchta, Miroslav
Rognes, Marie E.
Wohlmuth, Barbara
contents The flow of cerebrospinal fluid through the perivascular spaces of the brain is believed to play a crucial role in eliminating toxic waste proteins. While the driving forces of this flow have been enigmatic, experiments have shown that arterial wall motion is central. In this work, we present a network model for simulating pulsatile fluid flow in perivascular networks. We establish the well-posedness of this model in the primal and dual mixed variational settings, and show how it can be discretized using mixed finite elements. Further, we utilize this model to investigate fundamental questions concerning the physical mechanisms governing perivascular fluid flow. Notably, our findings reveal that arterial pulsations can induce directional flow in branching perivascular networks.
format Preprint
id arxiv_https___arxiv_org_abs_2401_00484
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Directional flow in perivascular networks: Mixed finite elements for reduced-dimensional models on graphs
Gjerde, Ingeborg G.
Kuchta, Miroslav
Rognes, Marie E.
Wohlmuth, Barbara
Analysis of PDEs
The flow of cerebrospinal fluid through the perivascular spaces of the brain is believed to play a crucial role in eliminating toxic waste proteins. While the driving forces of this flow have been enigmatic, experiments have shown that arterial wall motion is central. In this work, we present a network model for simulating pulsatile fluid flow in perivascular networks. We establish the well-posedness of this model in the primal and dual mixed variational settings, and show how it can be discretized using mixed finite elements. Further, we utilize this model to investigate fundamental questions concerning the physical mechanisms governing perivascular fluid flow. Notably, our findings reveal that arterial pulsations can induce directional flow in branching perivascular networks.
title Directional flow in perivascular networks: Mixed finite elements for reduced-dimensional models on graphs
topic Analysis of PDEs
url https://arxiv.org/abs/2401.00484