Diffusion Model based Semi-supervised Learning on Brain Hemorrhage Images for Efficient Midline Shift Quantification

Information processing in medical imaging : proceedings of the ... conference Pub Date : 2023-01-01 DOI:10.48550/arXiv.2301.00409

Shizhan Gong, Cheng Chen, Yuqi Gong, Nga Yan Chan, Wenao Ma, C. Mak, J. Abrigo, Q. Dou

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引用次数: 2

Abstract

Brain midline shift (MLS) is one of the most critical factors to be considered for clinical diagnosis and treatment decision-making for intracranial hemorrhage. Existing computational methods on MLS quantification not only require intensive labeling in millimeter-level measurement but also suffer from poor performance due to their dependence on specific landmarks or simplified anatomical assumptions. In this paper, we propose a novel semi-supervised framework to accurately measure the scale of MLS from head CT scans. We formulate the MLS measurement task as a deformation estimation problem and solve it using a few MLS slices with sparse labels. Meanwhile, with the help of diffusion models, we are able to use a great number of unlabeled MLS data and 2793 non-MLS cases for representation learning and regularization. The extracted representation reflects how the image is different from a non-MLS image and regularization serves an important role in the sparse-to-dense refinement of the deformation field. Our experiment on a real clinical brain hemorrhage dataset has achieved state-of-the-art performance and can generate interpretable deformation fields.

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基于扩散模型的半监督学习脑出血图像中线偏移定量研究

脑中线移位(MLS)是颅内出血临床诊断和治疗决策的关键因素之一。现有的MLS量化计算方法不仅需要在毫米级测量中进行密集标记，而且由于依赖于特定的标志或简化的解剖假设，性能较差。在本文中，我们提出了一种新的半监督框架来精确测量头部CT扫描的MLS尺度。我们将MLS测量任务描述为一个变形估计问题，并使用一些带有稀疏标签的MLS切片来解决它。同时，在扩散模型的帮助下，我们能够使用大量未标记的MLS数据和2793个非MLS案例进行表示学习和正则化。提取的图像表示反映了图像与非mls图像的不同之处，正则化在变形场的稀疏到密集细化中起着重要作用。我们在一个真实的临床脑出血数据集上的实验已经达到了最先进的性能，并且可以产生可解释的变形场。

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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Information processing in medical imaging : proceedings of the ... conference

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