A gradient-based approach to fast and accurate head motion compensation in cone-beam CT.

Mareike Thies, Fabian Wagner, Noah Maul, Haijun Yu, Manuela Goldmann, Linda-Sophie Schneider, Mingxuan Gu, Siyuan Mei, Lukas Folle, Alexander Preuhs, Michael Manhart, Andreas Maier
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Abstract

Cone-beam computed tomography (CBCT) systems, with their flexibility, present a promising avenue for direct point-of-care medical imaging, particularly in critical scenarios such as acute stroke assessment. However, the integration of CBCT into clinical workflows faces challenges, primarily linked to long scan duration resulting in patient motion during scanning and leading to image quality degradation in the reconstructed volumes. This paper introduces a novel approach to CBCT motion estimation using a gradient-based optimization algorithm, which leverages generalized derivatives of the backprojection operator for cone-beam CT geometries. Building on that, a fully differentiable target function is formulated which grades the quality of the current motion estimate in reconstruction space. We drastically accelerate motion estimation yielding a 19-fold speed-up compared to existing methods. Additionally, we investigate the architecture of networks used for quality metric regression and propose predicting voxel-wise quality maps, favoring autoencoder-like architectures over contracting ones. This modification improves gradient flow, leading to more accurate motion estimation. The presented method is evaluated through realistic experiments on head anatomy. It achieves a reduction in reprojection error from an initial average of 3 mm to 0.61 mm after motion compensation and consistently demonstrates superior performance compared to existing approaches. The analytic Jacobian for the backprojection operation, which is at the core of the proposed method, is made publicly available. In summary, this paper contributes to the advancement of CBCT integration into clinical workflows by proposing a robust motion estimation approach that enhances efficiency and accuracy, addressing critical challenges in time-sensitive scenarios.

基于梯度的方法,在锥束 CT 中实现快速准确的头部运动补偿。
锥形束计算机断层扫描(CBCT)系统以其灵活性为直接医疗点医学成像提供了一条大有可为的途径,尤其是在急性中风评估等关键场景中。然而,将 CBCT 集成到临床工作流程中面临着挑战,主要原因是扫描时间长,导致扫描过程中患者移动,从而导致重建体的图像质量下降。本文介绍了一种利用基于梯度的优化算法进行 CBCT 运动估计的新方法,该算法利用了锥形束 CT 几何结构的反投影算子的广义导数。在此基础上,制定了一个完全可变的目标函数,该函数可对重建空间中当前运动估计的质量进行分级。与现有方法相比,我们大大加快了运动估计的速度,提高了 19 倍。此外,我们还研究了用于质量度量回归的网络架构,并提出了预测体素质量图的建议,同时倾向于采用类似自动编码器的架构,而不是收缩架构。这种修改改善了梯度流,从而实现了更精确的运动估计。通过对头部解剖的实际实验,对所提出的方法进行了评估。经过运动补偿后,该方法可将重投影误差从最初的平均 3 毫米减少到 0.61 毫米,与现有方法相比始终表现出卓越的性能。作为该方法核心的反向投影操作的雅各布解析式已公开发表。总之,本文提出了一种稳健的运动估算方法,提高了效率和准确性,解决了时间敏感场景中的关键难题,为将 CBCT 集成到临床工作流程中做出了贡献。
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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