显微手术中用于增强现实可视化的立体校准

Stereoscopic calibration for augmented reality visualization in microscopic surgery.

作者信息

El Chemaly Trishia, Athayde Neves Caio, Leuze Christoph, Hargreaves Brian, H Blevins Nikolas

机构信息

Department of Bioengineering, Stanford University, Stanford, CA, USA.

Department of Otolaryngology, Stanford School of Medicine, Stanford, CA, USA.

出版信息

Int J Comput Assist Radiol Surg. 2023 Nov;18(11):2033-2041. doi: 10.1007/s11548-023-02980-5. Epub 2023 Jul 14.

DOI:10.1007/s11548-023-02980-5

PMID:37450175

Abstract

PURPOSE

Middle and inner ear procedures target hearing loss, infections, and tumors of the temporal bone and lateral skull base. Despite the advances in surgical techniques, these procedures remain challenging due to limited haptic and visual feedback. Augmented reality (AR) may improve operative safety by allowing the 3D visualization of anatomical structures from preoperative computed tomography (CT) scans on real intraoperative microscope video feed. The purpose of this work was to develop a real-time CT-augmented stereo microscope system using camera calibration and electromagnetic (EM) tracking.

METHODS

A 3D printed and electromagnetically tracked calibration board was used to compute the intrinsic and extrinsic parameters of the surgical stereo microscope. These parameters were used to establish a transformation between the EM tracker coordinate system and the stereo microscope image space such that any tracked 3D point can be projected onto the left and right images of the microscope video stream. This allowed the augmentation of the microscope feed of a 3D printed temporal bone with its corresponding CT-derived virtual model. Finally, the calibration board was also used for evaluating the accuracy of the calibration.

RESULTS

We evaluated the accuracy of the system by calculating the registration error (RE) in 2D and 3D in a microsurgical laboratory setting. Our calibration workflow achieved a RE of 0.11 ± 0.06 mm in 2D and 0.98 ± 0.13 mm in 3D. In addition, we overlaid a 3D CT model on the microscope feed of a 3D resin printed model of a segmented temporal bone. The system exhibited small latency and good registration accuracy.

CONCLUSION

We present the calibration of an electromagnetically tracked surgical stereo microscope for augmented reality visualization. The calibration method achieved accuracy within a range suitable for otologic procedures. The AR process introduces enhanced visualization of the surgical field while allowing depth perception.

摘要

目的

中耳和内耳手术旨在治疗听力损失、感染以及颞骨和侧颅底肿瘤。尽管手术技术有所进步，但由于触觉和视觉反馈有限，这些手术仍然具有挑战性。增强现实（AR）可通过在术中实际显微镜视频画面上呈现术前计算机断层扫描（CT）图像中的解剖结构的三维可视化，来提高手术安全性。本研究的目的是开发一种利用相机校准和电磁（EM）跟踪的实时CT增强立体显微镜系统。

方法

使用一个3D打印并电磁跟踪的校准板来计算手术立体显微镜的内参和外参。这些参数用于建立EM跟踪器坐标系与立体显微镜图像空间之间的转换关系，以便任何跟踪到的三维点都能投影到显微镜视频流的左右图像上。这使得一个3D打印的颞骨的显微镜画面能够与相应的CT衍生虚拟模型叠加。最后，校准板还用于评估校准的准确性。

结果

我们在显微外科实验室环境中通过计算二维和三维配准误差（RE）来评估系统的准确性。我们的校准流程在二维中的RE为0.11±0.06毫米，在三维中的RE为0.98±0.13毫米。此外，我们在一个分段颞骨的3D树脂打印模型的显微镜画面上叠加了一个三维CT模型。该系统显示出较小的延迟和良好的配准精度。

结论

我们展示了用于增强现实可视化的电磁跟踪手术立体显微镜的校准。该校准方法在适合耳科手术的范围内实现了高精度。AR过程在增强手术视野可视化的同时还能提供深度感知。

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显微手术中用于增强现实可视化的立体校准

Stereoscopic calibration for augmented reality visualization in microscopic surgery.

作者信息

机构信息

出版信息

PURPOSE

METHODS

RESULTS

CONCLUSION

目的

方法

结果

结论

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