Development of a patient-specific cerebral vasculature fluid–structure-interaction model

Development of in-silico models of patient-specific cerebral artery networks presents several significant technical challenges: (i) The resolution and smoothness of medical CT images are much lower than the required element/cell length for FEA/CFD/FSI models; (ii) contact between vessels, and indeed...

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Bibliographic Details
Published in:Journal of biomechanics 2022-03, Vol.133, p.110896-110896, Article 110896
Main Authors: Moerman, Kevin M., Konduri, Praneeta, Fereidoonnezhad, Behrooz, Marquering, Henk, van der Lugt, Aad, Luraghi, Giulia, Bridio, Sara, Migliavacca, Francesco, Rodriguez Matas, Jose F., McGarry, Patrick
Format: Article
Language:English
Subjects:
Algorithms
Arteries - physiology
Automation
Biomechanics
Blood clots
Blood flow
Blood vessels
Cerebral blood flow
Cerebral vessels
Clinical trials
Computed tomography
Computer applications
Computer Simulation
Customization
Elongation
Finite element method
Fluid Structure Interactions
Geometry
Hemodynamics
Humans
Hyperelastic
Image-based modelling
Interaction models
Ischemia
Medical equipment
Medical imaging
Models, Cardiovascular
Non-Newtonian Flow
Numerical analysis
Occlusion
Patients
Registration
Segments
Smoothness
Software
Strain distribution
Stroke
Thrombectomy
Tomography
Tortuosity
Veins & arteries
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Summary:Development of in-silico models of patient-specific cerebral artery networks presents several significant technical challenges: (i) The resolution and smoothness of medical CT images are much lower than the required element/cell length for FEA/CFD/FSI models; (ii) contact between vessels, and indeed self contact of high tortuosity vessel segments are not clearly identifiable from medical CT images. Commercial model construction software does not provide customised solutions for such technical challenges, with the result that accurate, efficient and automated development of patient-specific models of the cerebral vessels is not facilitated. This paper presents the development of a customised and highly automated platform for the generation of high resolution patient-specific FEA/CFD/FSI models from clinical images. This platform is used to perform the first fluid–structure-interaction patient-specific analysis of blood flow and artery deformation of an occluded cerebral vessel. Results demonstrate that in addition to flow disruption, clot occlusion significantly alters the geometry and strain distribution in the vessel network, with the blocked M2 segment undergoing axial elongation. The new computational approach presented in this study can be further developed as a clinical diagnostic tool and as a platform for thrombectomy device design.
ISSN:0021-9290
1873-2380
DOI:10.1016/j.jbiomech.2021.110896