Development and assessment of case-specific physical and augmented reality simulators for intracranial aneurysm clipping.

IF 3.2 Q1 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING

3D printing in medicine Pub Date : 2024-09-18 DOI:10.1186/s41205-024-00235-w

Lorenzo Civilla, Philippe Dodier, Maria Chiara Palumbo, Alberto C L Redaelli, Markus Koenigshofer, Ewald Unger, Torstein R Meling, Nikolay Velinov, Karl Rössler, Francesco Moscato

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引用次数: 0

Abstract

Background: Microsurgical clipping is a delicate neurosurgical procedure used to treat complex Unruptured Intracranial Aneurysms (UIAs) whose outcome is dependent on surgeon's experience. Simulations are emerging as excellent complements to standard training, but their adoption is limited by the realism they provide. The aim of this study was to develop and validate a microsurgical clipping simulator platform.

Methods: Physical and holographic simulators of UIA clipping have been developed. The physical phantom consisted of a 3D printed hard skull and five (n = 5) rapidly interchangeable, perfused and fluorescence compatible 3D printed aneurysm silicone phantoms. The holographic clipping simulation included a real-time finite-element-model of the aneurysm sac, allowing interaction with a virtual clip and its occlusion. Validity, usability, usefulness and applications of the simulators have been assessed through clinical scores for aneurysm occlusion and a questionnaire study involving 14 neurosurgical residents (R) and specialists (S) for both the physical (_p) and holographic (_h) simulators by scores going from 1 (very poor) to 5 (excellent).

Results: The physical simulator allowed to replicate successfully and accurately the patient-specific anatomy. UIA phantoms were manufactured with an average dimensional deviation from design of 0.096 mm and a dome thickness of 0.41 ± 0.11 mm. The holographic simulation executed at 25-50 fps allowing to gain unique insights on the anatomy and testing of the application of several clips without manufacturing costs. Aneurysm closure in the physical model evaluated by fluorescence simulation and post-operative CT revealed Raymond 1 (full) occlusion respectively in 68.89% and 73.33% of the cases. For both the simulators content validity, construct validity, usability and usefulness have been observed, with the highest scores observed in clip selection usefulness R_p=4.78, S_p=5.00 and R_h=4.00, S_h=5.00 for the printed and holographic simulators.

Conclusions: Both the physical and the holographic simulators were validated and resulted usable and useful in selecting valid clips and discarding unsuitable ones. Thus, they represent ideal platforms for realistic patient-specific simulation-based training of neurosurgical residents and hold the potential for further applications in preoperative planning.

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开发和评估用于颅内动脉瘤夹闭术的特定病例物理和增强现实模拟器。

背景：显微外科剪切术是一种精细的神经外科手术，用于治疗复杂的未破裂颅内动脉瘤（UIAs），其效果取决于外科医生的经验。模拟训练是对标准培训的极佳补充，但其采用受到其真实性的限制。本研究旨在开发和验证显微外科剪切模拟平台：方法：开发了 UIA 剪切的物理和全息模拟器。物理模型包括一个 3D 打印硬头骨和五个（n = 5）可快速互换、灌注和荧光兼容的 3D 打印动脉瘤硅胶模型。全息剪切模拟包括动脉瘤囊的实时有限元模型，允许与虚拟夹子及其闭塞进行交互。模拟器的有效性、可用性、实用性和应用已通过动脉瘤闭塞的临床评分和一项由 14 名神经外科住院医师（R）和专家（S）参与的问卷调查进行了评估，对物理（p）和全息（h）模拟器的评分从 1 分（非常差）到 5 分（优秀）不等：结果：物理模拟器能够成功、准确地复制病人的特定解剖结构。制造的 UIA 模型与设计的平均尺寸偏差为 0.096 毫米，穹顶厚度为 0.41 ± 0.11 毫米。全息模拟以 25-50 fps 的速度执行，从而获得了对解剖学的独特见解，并在不增加制造成本的情况下测试了多个夹子的应用。通过荧光模拟和术后 CT 评估物理模型中的动脉瘤闭合情况，分别有 68.89% 和 73.33% 的病例显示雷蒙德 1（完全）闭合。两种模拟器的内容效度、结构效度、可用性和实用性都得到了观察，其中印刷模拟器和全息模拟器在剪辑选择实用性方面的得分最高，分别为Rp=4.78，Sp=5.00和Rh=4.00，Sh=5.00：实物模拟器和全息模拟器都通过了验证，在选择有效剪辑和剔除不合适剪辑方面具有可用性和实用性。因此，它们是对神经外科住院医师进行基于特定患者的真实模拟培训的理想平台，并有望进一步应用于术前规划。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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3D printing in medicine

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5 weeks