P.152 In-vivo accuracy of pedicle screws utilizing a supervisory controlled 7DOF robot with OCT guidance

R. Johnston, M. Oppermann, V. Yang
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Abstract

Background: Pedicle screw fixation is an important technique in spine surgery. Violation of the pedicle can lead to neurovascular injury. Due to excellent pose repeatability, robotic technology may improve accuracy. Existing surgical spine robots use surgical assist architecture. This work explores the performance of a supervisory-control architecture robot (8i Robotics) for autonomous pedicle instrumentation. Methods: 3 porcine subjects underwent pedicle instrumentation utilizing the 7dof robot and were observed for 24 hours. Post-operative CT assessed screw location. Screws were graded clinically with the Gertzbein-Robbins Scale (GRS). Precision was assessed by a customized image processing pipeline. Euclidean error was calculated at screw head and screw tip. All points were normalized to a nominal screw, and confidence ellipses generated. Results: All animals were neurologically intact at 24 hours. All screws where GRS A. Mean tip and head Euclidean error where 2.47+/−1.25mm and 2.25+/-1.25mm respectively. Major and minor axes of the confidence ellipse at 99% was 2.19mm, and 1.28mm, and 2.07mm, and 0.42mm for tip and head respectively. Conclusions: 100% of screws obtained satisfactory clinical grading, with intact function in all animals post-operatively. This shows the capability of a supervisory-controlled 7DOF robot with OCT registration. Further investigation is warranted to further explore robotic capabilities, safety, and cost effectiveness.
P.152 利用监督控制的 7DOF 机器人和 OCT 引导,实现椎弓根螺钉的体内精确度
背景:椎弓根螺钉固定是脊柱手术中的一项重要技术。侵犯椎弓根可导致神经血管损伤。由于机器人技术具有出色的姿势可重复性,因此可以提高精确度。现有的脊柱手术机器人使用手术辅助结构。本研究探讨了监督控制架构机器人(8i Robotics)在自主椎弓根器械操作方面的性能。方法:使用 7dof 机器人对 3 头猪进行椎弓根器械植入术,并观察 24 小时。术后 CT 评估螺钉位置。使用格茨宾-罗宾斯量表(GRS)对螺钉进行临床分级。精确度由定制的图像处理管道进行评估。计算螺钉头和螺钉尖的欧氏误差。所有点均归一化为标称螺钉,并生成置信椭圆。结果24 小时后,所有动物的神经系统均完好无损。螺钉顶端和螺钉头部的平均欧氏误差分别为 2.47+/-1.25 毫米和 2.25+/-1.25毫米。置信度为 99% 的椭圆主轴和小轴分别为 2.19 毫米和 1.28 毫米,尖端和头部分别为 2.07 毫米和 0.42 毫米。结论100%的螺钉都获得了令人满意的临床分级,术后所有动物的功能都完好无损。这显示了带 OCT 注册的监督控制 7DOF 机器人的能力。有必要进行进一步研究,以进一步探索机器人的能力、安全性和成本效益。
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