Biomedical Engineering, Surgical Technologies Lab, Robert H.N. Ho Research Centre, University of British Columbia, 6th Floor, 2635 Laurel St, Vancouver, BC, V5Z 1M9, Canada.
Biomedical Engineering, Surgical Technologies Lab, University of British Columbia, Vancouver, Canada.
Int J Comput Assist Radiol Surg. 2018 Aug;13(8):1269-1282. doi: 10.1007/s11548-018-1776-9. Epub 2018 May 28.
Pedicle screw fixation is a challenging procedure with a concerning rates of reoperation. After insertion of the screws is completed, the most common intraoperative verification approach is to acquire anterior-posterior and lateral radiographic images, based on which the surgeons try to visually assess the correctness of insertion. Given the limited accuracy of the existing verification techniques, we identified the need for an accurate and automated pedicle screw assessment system that can verify the screw insertion intraoperatively. For doing so, this paper offers a framework for automatic segmentation and pose estimation of pedicle screws based on deep learning principles.
Segmentation of pedicle screw X-ray projections was performed by a convolutional neural network. The network could isolate the input X-rays into three classes: screw head, screw shaft and background. Once all the screw shafts were segmented, knowledge about the spatial configuration of the acquired biplanar X-rays was used to identify the correspondence between the projections. Pose estimation was then performed to estimate the 6 degree-of-freedom pose of each screw. The performance of the proposed pose estimation method was tested on a porcine specimen.
The developed machine learning framework was capable of segmenting the screw shafts with 93% and 83% accuracy when tested on synthetic X-rays and on clinically realistic X-rays, respectively. The pose estimation accuracy of this method was shown to be [Formula: see text] and [Formula: see text] on clinically realistic X-rays.
The proposed system offers an accurate and fully automatic pedicle screw segmentation and pose assessment framework. Such a system can help to provide an intraoperative pedicle screw insertion assessment protocol with minimal interference with the existing surgical routines.
椎弓根螺钉固定是一项具有挑战性的手术,其再手术率令人担忧。螺钉插入完成后,最常见的术中验证方法是获取前后位和侧位 X 线图像,根据这些图像,外科医生试图通过视觉评估插入的正确性。鉴于现有验证技术的准确性有限,我们发现需要一种准确且自动化的椎弓根螺钉评估系统,以便在术中验证螺钉的插入。为此,本文提出了一种基于深度学习原理的椎弓根螺钉自动分割和位姿估计框架。
基于卷积神经网络实现椎弓根螺钉 X 射线投影的分割。该网络可以将输入 X 射线分为三类:螺钉头、螺钉杆和背景。一旦所有的螺钉杆都被分割出来,就可以利用获得的双平面 X 射线的空间配置知识来识别投影之间的对应关系。然后进行位姿估计,以估计每个螺钉的 6 自由度位姿。在所提出的位姿估计方法的性能测试中,使用了猪标本。
所开发的机器学习框架能够在合成 X 射线和临床逼真 X 射线上分别以 93%和 83%的准确率分割螺钉杆。该方法的位姿估计准确率在临床逼真 X 射线上分别为[公式:见文本]和[公式:见文本]。
所提出的系统提供了一种准确且全自动的椎弓根螺钉分割和位姿评估框架。该系统有助于提供一种最小干扰现有手术常规的术中椎弓根螺钉插入评估方案。
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