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颅内动脉瘤血流导向装置的高保真虚拟支架置入(HiFiVS):体外和计算。

High fidelity virtual stenting (HiFiVS) for intracranial aneurysm flow diversion: in vitro and in silico.

机构信息

Toshiba Stroke and Vascular Research Center, University at Buffalo, State University of New York, 875 Ellicott Street, Buffalo, NY 14203, USA.

出版信息

Ann Biomed Eng. 2013 Oct;41(10):2143-56. doi: 10.1007/s10439-013-0808-4. Epub 2013 Apr 20.

DOI:10.1007/s10439-013-0808-4
PMID:23604850
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3766425/
Abstract

A flow diverter (FD) is a flexible, densely braided stent-mesh device placed endoluminally across an intracranial aneurysm to induce its thrombotic occlusion. FD treatment planning using computational virtual stenting and flow simulation requires accurate representation of the expanded FD geometry. We have recently developed a high fidelity virtual stenting (HiFiVS) technique based on finite element analysis to simulate detailed FD deployment processes in patient-specific aneurysms (Ma et al. J. Biomech. 45:2256-2263,(2012)). This study tests if HiFiVS simulation can recapitulate real-life FD implantation. We deployed two identical FDs (Pipeline Embolization Device) into phantoms of a wide-necked segmental aneurysm using a clinical push-pull technique with different delivery wire advancements. We then simulated these deployment processes using HiFiVS and compared results against experimental recording. Stepwise comparison shows that the simulations precisely reproduced the FD deployment processes recorded in vitro. The local metal coverage rate and pore density quantifications demonstrated that simulations reproduced detailed FD mesh geometry. These results provide validation of the HiFiVS technique, highlighting its unique capability of accurately representing stent intervention in silico.

摘要

血流导向装置(FD)是一种灵活的、密集编织的支架网装置,放置在颅内动脉瘤的管腔内,以诱导其血栓闭塞。使用计算性虚拟血管成形术和血流模拟进行 FD 治疗规划需要准确表示扩张的 FD 几何形状。我们最近开发了一种基于有限元分析的高保真虚拟血管成形术(HiFiVS)技术,以模拟特定于患者的动脉瘤中的详细 FD 部署过程(Ma 等人,J. Biomech. 45:2256-2263,(2012))。这项研究测试了 HiFiVS 模拟是否可以再现真实的 FD 植入。我们使用临床推挽技术将两个相同的 FD(Pipeline Embolization Device)部署到一个宽颈节段性动脉瘤的体模中,该技术使用了不同的输送线推进。然后,我们使用 HiFiVS 模拟这些部署过程,并将结果与实验记录进行比较。逐步比较表明,模拟精确地再现了体外记录的 FD 部署过程。局部金属覆盖率和孔密度的量化表明,模拟再现了详细的 FD 网格几何形状。这些结果验证了 HiFiVS 技术,突出了其在虚拟环境中准确表示支架干预的独特能力。

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