Le Bras Anthony, Boustia Fakhreddine, Janot Kevin, Le Pabic Estelle, Ouvrard Mathilde, Fougerou-Leurent Claire, Ferre Jean-Christophe, Gauvrit Jean-Yves, Eugene François
Service de Radiologie, Centre Hospitalier Bretagne Atlantique, France; Service de Radiologie, Centre Hospitalier Universitaire de Rennes, France.
Service de Radiologie, Centre Hospitalier Universitaire de Rennes, France.
J Neuroradiol. 2023 Feb;50(1):86-92. doi: 10.1016/j.neurad.2021.11.008. Epub 2021 Dec 13.
In neurovascular treatment planning, endovascular devices to manage complex intracranial aneurysms requiring intervention are often selected based on conventional measurements and interventional neuroradiologist experience. A recently developed technology allows a patient-specific 3D-printed model to mimic the navigation experience. The goal of this study was to assess the effect of pre-procedure 3D simulation on procedural and clinical outcomes for wide-neck aneurysm embolization.
MATERIALS & METHODS: In this unblinded, non-randomized, prospective, multicenter study conducted from November 18 through December 20, patients with complex intracranial aneurysms (neck > 4 mm or ratio < 2) were treated by WEB or flow diverter stents (FDS). The primary endpoint was concordance between simulation and procedure, 3D-printed model accuracy as well as embolization outcomes including complications, procedure times, and radiation dose were also assessed. Secondary endpoint was to compare versus a retrospective WEB cohort.
Twenty-one patients were treated, 76% of cases by WEB and 24% by FDS. Concordance between post-simulation and real procedure efficiency was 0.85 [0.69 - 1.00] for size device selection and 0.93 [0.79 - 1.00] for wall-apposition/aneurysm neck closure. Geometrical accuracy of the 3D-printed model showed a mean absolute shift of 0.11 mm. Two complications without major clinical impact were reported with a post-operative mRS similar to pre-procedure mRS for all patients.
Rehearsal using accurate 3D-printed patient-specific aneurysm models enabled optimization of embolization strategy, resulting in reduced procedure duration and cumulative fluoroscopy time which translated to reduced radiation exposure compared to procedures performed without simulation.
在神经血管治疗规划中,用于处理需要干预的复杂颅内动脉瘤的血管内装置通常是根据传统测量方法和介入神经放射科医生的经验来选择的。最近开发的一项技术允许使用患者特异性的3D打印模型来模拟导航体验。本研究的目的是评估术前3D模拟对宽颈动脉瘤栓塞的手术和临床结果的影响。
在这项于11月18日至12月20日进行的非盲、非随机、前瞻性、多中心研究中,患有复杂颅内动脉瘤(颈部>4mm或比率<2)的患者接受了WEB或血流导向支架(FDS)治疗。主要终点是模拟与手术的一致性,还评估了3D打印模型的准确性以及包括并发症、手术时间和辐射剂量在内的栓塞结果。次要终点是与回顾性WEB队列进行比较。
治疗了21例患者,76%的病例采用WEB治疗,24%采用FDS治疗。在尺寸装置选择方面,模拟后与实际手术效率的一致性为0.85[0.69 - 1.00],在贴壁/动脉瘤颈部闭合方面为0.93[0.79 - 1.00]。3D打印模型的几何精度显示平均绝对偏移为0.11mm。报告了2例无重大临床影响的并发症,所有患者术后改良Rankin量表(mRS)与术前mRS相似。
使用精确的患者特异性动脉瘤3D打印模型进行预演能够优化栓塞策略,与未进行模拟的手术相比,减少了手术持续时间和累积透视时间,从而减少了辐射暴露。
