用于腹腔镜手术的 SLAM 辅助 3D 跟踪系统

Jingwei Song, Ray Zhang, Wenwei Zhang, Hao Zhou, Maani Ghaffari
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引用次数: 0

摘要

微创手术的一个主要局限是,由于缺乏触觉反馈和透明度,很难准确定位目标器官的内部解剖结构。增强现实技术(AR)为克服这一难题提供了一个前景广阔的解决方案。大量研究表明,结合基于学习的方法和几何方法可以实现术前和术中数据的精确配准。本研究提出了一种用于术后配准任务的全时单目三维跟踪算法。该算法采用 ORB-SLAM2 框架,并对其进行了修改,用于基于先验的三维跟踪。原始三维形状用于单目 SLAM 的快速初始化。采用伪分割策略将目标器官从背景中分离出来进行跟踪,并将三维形状的几何先验值作为附加约束纳入姿态图中。体内和体外实验证明,所提出的三维跟踪系统能提供稳健的三维跟踪,并能有效处理快速运动、视场外场景、部分可见性和 "器官-背景 "相对运动等典型挑战。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
SLAM assisted 3D tracking system for laparoscopic surgery
A major limitation of minimally invasive surgery is the difficulty in accurately locating the internal anatomical structures of the target organ due to the lack of tactile feedback and transparency. Augmented reality (AR) offers a promising solution to overcome this challenge. Numerous studies have shown that combining learning-based and geometric methods can achieve accurate preoperative and intraoperative data registration. This work proposes a real-time monocular 3D tracking algorithm for post-registration tasks. The ORB-SLAM2 framework is adopted and modified for prior-based 3D tracking. The primitive 3D shape is used for fast initialization of the monocular SLAM. A pseudo-segmentation strategy is employed to separate the target organ from the background for tracking purposes, and the geometric prior of the 3D shape is incorporated as an additional constraint in the pose graph. Experiments from in-vivo and ex-vivo tests demonstrate that the proposed 3D tracking system provides robust 3D tracking and effectively handles typical challenges such as fast motion, out-of-field-of-view scenarios, partial visibility, and "organ-background" relative motion.
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