Trishia El Chemaly, Caio Athayde Neves, Fanrui Fu, Brian Hargreaves, Nikolas H Blevins
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引用次数: 0
Abstract
Purpose: The operating microscope plays a central role in middle and inner ear procedures that involve working within tightly confined spaces under limited exposure. Augmented reality (AR) may improve surgical guidance by combining preoperative computed tomography (CT) imaging that can provide precise anatomical information, with intraoperative microscope video feed. With current technology, the operator must manually interact with the AR interface using a computer. The latter poses a disruption in the surgical flow and is suboptimal for maintaining the sterility of the operating environment. The purpose of this study was to implement and evaluate free-hand interaction concepts leveraging hand tracking and gesture recognition as an attempt to reduce the disruption during surgery and improve human-computer interaction.
Methods: An electromagnetically tracked surgical microscope was calibrated using a custom 3D printed calibration board. This allowed the augmentation of the microscope feed with segmented preoperative CT-derived virtual models. Ultraleap's Leap Motion Controller 2 was coupled to the microscope and used to implement hand-tracking capabilities. End-user feedback was gathered from a surgeon during development. Finally, users were asked to complete tasks that involved interacting with the virtual models, aligning them to physical targets, and adjusting the AR visualization.
Results: Following observations and user feedback, we upgraded the functionalities of the hand interaction system. User feedback showed the users' preference for the new interaction concepts that provided minimal disruption of the surgical workflow and more intuitive interaction with the virtual content.
Conclusion: We integrated hand interaction concepts, typically used with head-mounted displays (HMDs), into a surgical stereo microscope system intended for AR in otologic microsurgery. The concepts presented in this study demonstrated a more favorable approach to human-computer interaction in a surgical context. They hold potential for a more efficient execution of surgical tasks under microscopic AR guidance.
目的:手术显微镜在中耳和内耳手术中发挥着核心作用,这些手术需要在狭小的空间和有限的暴露条件下进行。术前计算机断层扫描(CT)成像可提供精确的解剖信息,而术中显微镜视频则可提供精确的解剖信息,因此增强现实(AR)技术可改善手术指导。就目前的技术而言,操作员必须使用计算机与 AR 界面进行手动交互。后者会干扰手术流程,而且不利于保持手术环境的无菌性。本研究的目的是利用手部跟踪和手势识别技术,实施和评估自由手部交互概念,以减少手术过程中的干扰,改善人机交互:方法:使用定制的 3D 打印校准板校准电磁跟踪手术显微镜。方法:使用定制的三维打印校准板对电磁跟踪手术显微镜进行校准,这样就可以利用分段的术前 CT 导出虚拟模型来增强显微镜馈送。Ultraleap 的 Leap Motion Controller 2 与显微镜相连,用于实现手部追踪功能。在开发过程中,从一名外科医生那里收集了最终用户的反馈意见。最后,要求用户完成与虚拟模型交互、将虚拟模型与物理目标对齐以及调整 AR 可视化的任务:根据观察和用户反馈,我们升级了手部交互系统的功能。用户反馈显示,用户更喜欢新的交互概念,因为它能最大限度地减少对手术工作流程的干扰,并与虚拟内容进行更直观的交互:我们将通常与头戴式显示器(HMD)一起使用的手部交互概念集成到了耳科显微外科 AR 手术立体显微镜系统中。本研究提出的概念展示了在外科手术中进行人机交互的一种更有利的方法。它们为在显微 AR 引导下更高效地执行外科手术任务提供了可能性。
期刊介绍:
The International Journal for Computer Assisted Radiology and Surgery (IJCARS) is a peer-reviewed journal that provides a platform for closing the gap between medical and technical disciplines, and encourages interdisciplinary research and development activities in an international environment.