Pelphix: Surgical Phase Recognition from X-ray Images in Percutaneous Pelvic Fixation.

Benjamin D Killeen, Han Zhang, Jan Mangulabnan, Mehran Armand, Russell H Taylor, Greg Osgood, Mathias Unberath
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Abstract

Surgical phase recognition (SPR) is a crucial element in the digital transformation of the modern operating theater. While SPR based on video sources is well-established, incorporation of interventional X-ray sequences has not yet been explored. This paper presents Pelphix, a first approach to SPR for X-ray-guided percutaneous pelvic fracture fixation, which models the procedure at four levels of granularity - corridor, activity, view, and frame value - simulating the pelvic fracture fixation workflow as a Markov process to provide fully annotated training data. Using added supervision from detection of bony corridors, tools, and anatomy, we learn image representations that are fed into a transformer model to regress surgical phases at the four granularity levels. Our approach demonstrates the feasibility of X-ray-based SPR, achieving an average accuracy of 99.2% on simulated sequences and 71.7% in cadaver across all granularity levels, with up to 84% accuracy for the target corridor in real data. This work constitutes the first step toward SPR for the X-ray domain, establishing an approach to categorizing phases in X-ray-guided surgery, simulating realistic image sequences to enable machine learning model development, and demonstrating that this approach is feasible for the analysis of real procedures. As X-ray-based SPR continues to mature, it will benefit procedures in orthopedic surgery, angiography, and interventional radiology by equipping intelligent surgical systems with situational awareness in the operating room.

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Pelphix:从 X 光图像识别经皮骨盆固定术中的手术期。
手术相位识别(SPR)是现代手术室数字化转型的关键因素。虽然基于视频源的 SPR 已经得到广泛认可,但将介入性 X 射线序列纳入其中的做法尚未得到探索。本文介绍了 Pelphix,这是第一种用于 X 光引导下经皮骨盆骨折固定的 SPR 方法,它从走廊、活动、视图和帧值四个粒度层面对手术过程进行建模,将骨盆骨折固定工作流程模拟为马尔可夫过程,从而提供完全注释的训练数据。通过对骨走廊、工具和解剖结构的检测,我们学习了图像表征,并将其输入变换器模型,从而在四个粒度水平上对手术阶段进行回归。我们的方法证明了基于 X 射线的 SPR 的可行性,在所有粒度水平上,模拟序列的平均准确率达到 99.2%,在尸体中达到 71.7%,在真实数据中,目标走廊的准确率高达 84%。这项工作迈出了 X 射线领域 SPR 的第一步,建立了 X 射线引导手术中阶段分类的方法,模拟了真实的图像序列以实现机器学习模型的开发,并证明了这种方法在真实手术分析中的可行性。随着基于 X 射线的 SPR 技术的不断成熟,它将通过为智能手术系统配备手术室中的态势感知功能,使骨科手术、血管造影术和介入放射学手术受益匪浅。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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