RoboticScope-Assisted Microanastomosis in a Chicken Leg Model.

Asian journal of neurosurgery Pub Date : 2023-12-29 eCollection Date: 2023-12-01 DOI:10.1055/s-0043-1776794
Adi Ahmetspahic, Eldin Burazerovic, Dragan Jankovic, Eleonora Kujaca, Hana Rizvanovic, Ibrahim Omerhodzic, Haso Sefo, Nermir Granov
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Abstract

Background  Many recent studies show that exoscopes are safe and effective alternatives to operating microscopes (OM). Developments of robotics and automation are present in neurosurgery with the appearance of a newer device such as RoboticScope (RS) exoscope with a digital three-dimensional (3D) image and a head-mounted display. The body of the RS is connected to a six-axis robotic arm that contains two video cameras, and serves as stereovision. This robotic arm allows accurate 3D camera motions over the field of view, giving the user a great degree of freedom in viewpoint selection. The surgeons may specify the direction and speed of the robotic arm using simple head movements when the foot pedal is pressed. Since its development in 2020, the RS has occasionally been used in neurosurgery for a multitude of procedures. Methods  This study showcases vessel microanastomosis training on chicken legs using the RS. The aim of this study is to demonstrate the feasibility of the RS without a comparative analysis of the standard OM. The study was conducted in 2023 during a month-long trial period of the device at the Department of Neurosurgery of the Clinical Center of the University of Sarajevo. All procedures including RS-assisted anastomosis were performed by a neurosurgeon in anastomosis training (A.A.) supervised by a senior vascular neurosurgeon (E.B.). For the purpose of the study, we evaluated occlusion time in minutes, bypass patency with iodine, and overall satisfaction of the trainee in terms of light intensity, precision of automatic focus, mobility of the device, ergonomics, and convenience of the helmet. Results  Ten RS-assisted microanastomoses were performed by interrupted suturing technique with 10.0 nylon thread. Bypass training included seven "end-to-side," two "end-to-end," and one "side-to-side" microanastomoses. The smallest vessel diameter was 1 mm. Occlusion time improved by training from 50 to 24 minutes, with contrast patency of the anastomoses in all cases without notable leakage of the contrast, except one case. Complete satisfaction of the trainee was achieved in 7 out of 10 cases. During this period, we also performed different RS-assisted surgeries including a single indirect bypass, convexity brain tumor resection, and microdiscectomies. Conclusion  RS provides a new concept for microanastomosis training as an alternative or adjunct to the standard microscope. We found a full-time hands-on microsuturing without the need for manual readjustment of the device as an advantage as well as instant depth at automatic zooming and precise transposition of the focus via head movements. However, it takes time to adapt and get used to the digital image. With the evolution of the device helmet's shortcomings, the RS could represent a cutting-edge method in vessel microanastomosis in the future. Nevertheless, this article represents one of the first written reports on microanastomosis training on an animal model with the above-mentioned device.

鸡腿模型中的机器人窥镜辅助微吻合术
背景 最近的许多研究表明,外窥镜是手术显微镜(OM)安全有效的替代品。随着机器人和自动化技术的发展,神经外科出现了一种较新的设备,如带有数字三维(3D)图像和头戴式显示器的机器人外窥镜(RS)。RS 的机身与一个六轴机械臂相连,机械臂上装有两台摄像机,用作立体视觉。该机械臂可在视野内进行精确的三维摄像运动,使用户在选择视点时有很大的自由度。外科医生可以在按下脚踏板时,通过简单的头部运动来指定机械臂的方向和速度。自 2020 年开发以来,RS 偶尔会用于神经外科的多种手术。方法 本研究展示了使用 RS 在鸡腿上进行血管微吻合训练。本研究旨在展示 RS 的可行性,而不对标准 OM 进行比较分析。这项研究于 2023 年在萨拉热窝大学临床中心神经外科进行,当时该设备正在进行为期一个月的试用。包括 RS 辅助吻合术在内的所有手术均由一名接受过吻合术培训的神经外科医生(A.A.)在一名资深血管神经外科医生(E.B.)的指导下完成。在研究中,我们评估了以分钟为单位的闭塞时间、碘伏下的旁路通畅度,以及受训者在光照强度、自动聚焦的精确度、设备的移动性、人体工程学和头盔的便利性等方面的总体满意度。结果 使用 10.0 尼龙线,通过间断缝合技术完成了 10 例 RS 辅助微吻合术。旁路训练包括七次 "端对端"、两次 "端对端 "和一次 "侧对侧 "微吻合。最小血管直径为 1 毫米。通过培训,闭塞时间从 50 分钟缩短到 24 分钟,除一例外,所有吻合口均造影剂通畅,造影剂无明显渗漏。在 10 个病例中,有 7 个让受训者完全满意。在此期间,我们还进行了不同的 RS 辅助手术,包括单个间接分流术、凸面脑肿瘤切除术和显微椎间盘切除术。结论 RS 为显微吻合术培训提供了一个新概念,可作为标准显微镜的替代或辅助工具。我们发现,无需手动重新调整设备即可进行全时显微缝合的优势,以及自动变焦和通过头部移动精确转移焦点的即时深度。不过,适应和习惯数字图像需要时间。随着设备头盔缺点的不断改进,RS 将成为未来血管微吻合的尖端方法。尽管如此,这篇文章代表了使用上述设备在动物模型上进行微吻合训练的首批书面报告之一。
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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