新型聚酰亚胺立体定向脑电深度电极的植入精度--人体尸体研究

Aura Kullmann, Farida Akberali, Jaime J. Van Gompel, Robert A. McGovern, W. R. Marsh, Debra Kridner, Camilo A. Diaz-Botia, Michael C. Park
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摘要

立体脑电图(sEEG)是一种微创手术,利用立体植入大脑结构的深度电极来绘制癫痫患者癫痫发作的起源和传播图。sEEG 电极的植入准确性对手术的安全性和有效性起着至关重要的作用。四名神经外科医生(使用者)借助 ROSA 机器人系统在两个尸体头部植入了 24 个 sEEG 电极。可用性评估采用问卷调查的方式,评估每个 IFU 所有操作步骤的完成情况和用户错误。为了评估植入的准确性,在融合术前和术后的计算机断层扫描(CT)图像后,将计划的电极轨迹与植入后的轨迹进行比较。所有 sEEG 电极均按照 IFU 成功植入,未出现用户误差,对用户的植入后调查显示操作特性良好。EPE 为 1.28 ± 0.86 毫米,TPE 为 1.61 ± 0.89 毫米。长轨迹(>50 毫米)的 EPE 和 TPE 明显大于短轨迹(<50 毫米),正交和斜交轨迹之间没有差异。结果表明,新开发的聚酰亚胺 sEEG 电极在模拟临床环境中按照 IFU 进行植入时,与标记物中的类似设备一样精确,不会出现用户误差。由于人体尸体的大小、解剖结构和组织成分与活体人脑相似,因此人体尸体体外测试系统提供了一个逼真的测试系统。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Implantation accuracy of novel polyimide stereotactic electroencephalographic depth electrodes—a human cadaveric study
Stereoelectroencephalography (sEEG) is a minimally invasive procedure that uses depth electrodes stereotactically implanted into brain structures to map the origin and propagation of seizures in epileptic patients. Implantation accuracy of sEEG electrodes plays a critical role in the safety and efficacy of the procedure. This study used human cadaver heads, simulating clinical practice, to evaluate (1) neurosurgeon's ability to implant a new thin-film polyimide sEEG electrode according to the instructions for use (IFU), and (2) implantation accuracy.Four neurosurgeons (users) implanted 24 sEEG electrodes into two cadaver heads with the aid of the ROSA robotic system. Usability was evaluated using a questionnaire that assessed completion of all procedure steps per IFU and user errors. For implantation accuracy evaluation, planned electrode trajectories were compared with post-implantation trajectories after fusion of pre- and postoperative computer tomography (CT) images. Implantation accuracy was quantified using the Euclidean distance for entry point error (EPE) and target point error (TPE).All sEEG electrodes were successfully placed following the IFU without user errors, and post-implant survey of users showed favorable handling characteristics. The EPE was 1.28 ± 0.86 mm and TPE was 1.61 ± 0.89 mm. Long trajectories (>50 mm) had significantly larger EPEs and TPEs than short trajectories (<50 mm), and no differences were found between orthogonal and oblique trajectories. Accuracies were similar or superior to those reported in the literature when using similar experimental conditions, and in the same range as those reported in patients.The results demonstrate that newly developed polyimide sEEG electrodes can be implanted as accurately as similar devices in the marker without user errors when following the IFU in a simulated clinical environment. The human cadaver ex-vivo test system provided a realistic test system, owing to the size, anatomy and similarity of tissue composition to that of the live human brain.
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