开发和验证一种用于口腔颌面外科中铣削个体化颌骨腔的机器人系统。
Development and validation of a robotic system for milling individualized jawbone cavities in oral and maxillofacial surgery.
机构信息
State Key Laboratory of Oral & Maxillofacial Reconstruction and Regeneration, National Clinical Research Center for Oral Diseases, Shaanxi Key Laboratory of Stomatology, Digital Center, School of Stomatology, The Fourth Military Medical University, No.145 Changle West Road, Xincheng District, Xi'an, Shaanxi 710032, China.
Beijing Yakebot Technology Co., Ltd., Beijing, China.
出版信息
J Dent. 2024 Nov;150:105380. doi: 10.1016/j.jdent.2024.105380. Epub 2024 Sep 30.
OBJECTIVES
This study aimed to develop and validate a robotic system capable of performing accurate and minimally invasive jawbone milling procedures in oral and maxillofacial surgery.
METHODS
The robotic hardware system mainly includes a UR5E arm (Universal Robots, Denmark) and the binocular positioning system (FusionTrack 250, Atracsys LLC, Switzerland). The robotic software (Dental Navi 3.0.0, Yakebot Technology Ltd., China) is capable of generating cutting tool paths based on three-dimensional shape description files, typically in the stereolithography format, and selected cutting tool parameters, as well as designing surgical accessories. Fully impacted supernumerary tooth models in the maxilla were fabricated using software and three-dimensional printing. Following the planning of a customized cavity to fully expose the tooth, maxillary bone milling was performed on both the robot and static guide groups (n = 8). After milling, all models underwent scanning for assessment.
RESULTS
In the experiment with fully buried supernumerary tooth models in the maxilla, the root mean square, translation error, over-removal rate, and maximum distance were significantly smaller in the robot group compared to the static guide group. Moreover, the overlap ratio and Dice coefficient were significantly greater in the robot group. No statistically significant differences were observed between the two groups in terms of the rotation error (P = 0.80) or under-removal rate (P = 0.92).
CONCLUSIONS
This study has developed a robotic system for milling individualized jawbone cavities in oral and maxillofacial surgery, and its accuracy has been preliminarily verified to meet clinical requirements.
CLINICAL SIGNIFICANCE
The robotic system can achieve precise, minimally invasive, individualized jawbone milling in a variety of oral and maxillofacial surgeries, including tooth autotransplantation, surgical reshaping for zygomatic fibrous dysplasia, removal of fully impacted supernumerary or impacted teeth, and endodontic microsurgery, among other relevant clinical applications.
目的
本研究旨在开发和验证一种能够在口腔颌面外科中进行精确、微创的颌骨铣削手术的机器人系统。
方法
机器人硬件系统主要包括 UR5E 机械臂(丹麦 Universal Robots 公司)和双目定位系统(瑞士 AtracsysLLC 公司的 FusionTrack250)。机器人软件(中国 Yakebot 科技有限公司的 DentalNavi3.0.0)能够根据三维形状描述文件(通常为立体光固化格式)和选定的刀具参数生成刀具路径,并设计手术附件。使用软件和三维打印技术制作上颌完全埋伏多生牙模型。在规划出一个定制的腔以充分暴露牙齿后,在机器人组和静态导向组(n=8)上进行上颌骨铣削。铣削后,所有模型都进行扫描评估。
结果
在实验中,对于上颌完全埋伏的多生牙模型,机器人组的根均方误差、平移误差、过切率和最大距离明显小于静态导向组。此外,机器人组的重叠比和 Dice 系数明显更大。两组之间的旋转误差(P=0.80)和欠切率(P=0.92)没有统计学差异。
结论
本研究开发了一种用于口腔颌面外科个性化颌骨腔铣削的机器人系统,其精度已初步验证符合临床要求。
临床意义
该机器人系统可以在各种口腔颌面外科手术中实现精确、微创、个体化的颌骨铣削,包括牙齿自体移植、颧骨纤维结构不良的手术整形、完全埋伏或阻生牙的去除、以及根管显微镜手术等相关临床应用。
Zotero 插件