1. Modeling Flow Diverters Using a Porous Medium Approach: A Fast Alternative to Virtual Flow Diverter Deployment.
- Author
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Xu, Jinyu, Karmonik, Christof, Yu, Ying, Lv, Nan, Shi, Zhaoyue, Liu, Jian-Min, and Huang, Qinghai
- Subjects
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POROUS materials , *COMPUTATIONAL fluid dynamics , *SHEARING force , *SHEAR walls - Abstract
The Tubridge flow diverter (FD) (MicroPort Medical Co. Ltd., Shanghai, China) is a novel device aimed at reconstructing the parent artery and eliminating the aneurysm. Numerical simulations based on virtual FD deployment allow the assessment of the complex nature of aneurismal flow changes before the actual intervention but are demanding on computational resources. Here, we evaluate an alternative strategy of modeling FD effects for the Tubridge system using a porous medium. The goal of this study is to reduce demands on time and complexity of the simulation procedure for applications in clinical research. Ten patient-specific aneurysm models were reconstructed from retrospectively collected diagnostic 3-dimensional digital subtraction angiographic images. Virtual FDs were deployed (SolidWorks, Dassault Systems, Concord, Massachusetts, USA; Meshmixer, Autodesk, San Rafael, California, USA) and corresponding porous medium patches were constructed at the ostium with a research computational fluid dynamics prototype (Siemens Healthineers, Forchheim, Germany). Hemodynamic conditions were simulated in 2 approaches. Hemodynamics inside the aneurysm based on these 2 approaches were compared. Both approaches yielded similar results. Mean wall shear stress and mean pressure of the aneurysmal wall correlated significantly (r = 0.8, r = 1.0, P < 0.05) as did mean velocity and mean pressure at a region inside the aneurysm, at the ostium and at a cross section containing the main vertex (for velocities r = 0.9; for pressures r = 1.0, P < 0.05). The use of porous medium patches reduced the preparation and simulation time together by approximately 50%. Using a porous medium approach yields comparable mean values for hemodynamic alterations compared to direct virtual FD simulations. Additionally, the porous medium approach greatly reduced the modeling complexity and computation time. [ABSTRACT FROM AUTHOR]
- Published
- 2022
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