Motion artifacts can compromise the diagnostic value of computed tomography (CT) images. Motion correction approaches require a per-scan estimation of patient-specific motion patterns. In this work, we train a score-based model to act as a probability density estimator for clean head CT images. Given the trained model, we quantify the deviation of a given motion-affected CT image from the ideal distribution through likelihood computation. We demonstrate that the likelihood can be utilized as a surrogate metric for motion artifact severity in the CT image facilitating the application of an iterative, gradient-based motion compensation algorithm. By optimizing the underlying motion parameters to maximize likelihood, our method effectively reduces motion artifacts, bringing the image closer to the distribution of motion-free scans. Our approach achieves comparable performance to state-of-the-art methods while eliminating the need for a representative data set of motion-affected samples. This is particularly advantageous in real-world applications, where patient motion patterns may exhibit unforeseen variability, ensuring robustness without implicit assumptions about recoverable motion types.
@article{arxiv.2404.14747,
title = {Differentiable Score-Based Likelihoods: Learning CT Motion Compensation From Clean Images},
author = {Mareike Thies and Noah Maul and Siyuan Mei and Laura Pfaff and Nastassia Vysotskaya and Mingxuan Gu and Jonas Utz and Dennis Possart and Lukas Folle and Fabian Wagner and Andreas Maier},
journal= {arXiv preprint arXiv:2404.14747},
year = {2024}
}