TY - JOUR
T1 - Numerical simulation of endovascular treatment options for cerebral aneurysms
AU - Frank, Martin
AU - Holzberger, Fabian
AU - Horvat, Medeea
AU - Kirschke, Jan
AU - Mayr, Matthias
AU - Muhr, Markus
AU - Nebulishvili, Natalia
AU - Popp, Alexander
AU - Schwarting, Julian
AU - Wohlmuth, Barbara
N1 - Publisher Copyright:
© 2024 The Authors. GAMM - Mitteilungen published by Wiley-VCH GmbH.
PY - 2024
Y1 - 2024
N2 - Predicting the long-term success of endovascular interventions in the clinical management of cerebral aneurysms requires detailed insight into the patient-specific physiological conditions. In this work, we not only propose numerical representations of endovascular medical devices such as coils, flow diverters or Woven EndoBridge but also outline numerical models for the prediction of blood flow patterns in the aneurysm cavity right after a surgical intervention. Detailed knowledge about the postsurgical state then lays the basis to assess the chances of a stable occlusion of the aneurysm required for a long-term treatment success. To this end, we propose mathematical and mechanical models of endovascular medical devices made out of thin metal wires. These can then be used for fully resolved flow simulations of the postsurgical blood flow, which in this work will be performed by means of a Lattice Boltzmann method applied to the incompressible Navier–Stokes equations and patient-specific geometries. To probe the suitability of homogenized models, we also investigate poro-elastic models to represent such medical devices. In particular, we examine the validity of this modeling approach for flow diverter placement across the opening of the aneurysm cavity. For both approaches, physiologically meaningful boundary conditions are provided from reduced-order models of the vascular system. The present study demonstrates our capabilities to predict the postsurgical state and lays a solid foundation to tackle the prediction of thrombus formation and, thus, the aneurysm occlusion in a next step.
AB - Predicting the long-term success of endovascular interventions in the clinical management of cerebral aneurysms requires detailed insight into the patient-specific physiological conditions. In this work, we not only propose numerical representations of endovascular medical devices such as coils, flow diverters or Woven EndoBridge but also outline numerical models for the prediction of blood flow patterns in the aneurysm cavity right after a surgical intervention. Detailed knowledge about the postsurgical state then lays the basis to assess the chances of a stable occlusion of the aneurysm required for a long-term treatment success. To this end, we propose mathematical and mechanical models of endovascular medical devices made out of thin metal wires. These can then be used for fully resolved flow simulations of the postsurgical blood flow, which in this work will be performed by means of a Lattice Boltzmann method applied to the incompressible Navier–Stokes equations and patient-specific geometries. To probe the suitability of homogenized models, we also investigate poro-elastic models to represent such medical devices. In particular, we examine the validity of this modeling approach for flow diverter placement across the opening of the aneurysm cavity. For both approaches, physiologically meaningful boundary conditions are provided from reduced-order models of the vascular system. The present study demonstrates our capabilities to predict the postsurgical state and lays a solid foundation to tackle the prediction of thrombus formation and, thus, the aneurysm occlusion in a next step.
KW - cerebral aneurysm
KW - endovascular intervention
KW - finite elements
KW - Lattice Boltzmann method
KW - patient-specific simulation
KW - porous medium
UR - http://www.scopus.com/inward/record.url?scp=85198704784&partnerID=8YFLogxK
U2 - 10.1002/gamm.202370007
DO - 10.1002/gamm.202370007
M3 - Article
AN - SCOPUS:85198704784
SN - 0936-7195
JO - GAMM Mitteilungen
JF - GAMM Mitteilungen
ER -