Consistency-guided Differential Decoding for Enhancing Semi-supervised Medical Image Segmentation.

Qingjie Zeng, Yutong Xie, Zilin Lu, Mengkang Lu, Jingfeng Zhang, Yuyin Zhou, Yong Xia
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Abstract

Semi-supervised learning (SSL) has been proven beneficial for mitigating the issue of limited labeled data, especially on volumetric medical image segmentation. Unlike previous SSL methods which focus on exploring highly confident pseudo-labels or developing consistency regularization schemes, our empirical findings suggest that differential decoder features emerge naturally when two decoders strive to generate consistent predictions. Based on the observation, we first analyze the treasure of discrepancy in learning towards consistency, under both pseudo-labeling and consistency regularization settings, and subsequently propose a novel SSL method called LeFeD, which learns the feature-level discrepancies obtained from two decoders, by feeding such information as feedback signals to the encoder. The core design of LeFeD is to enlarge the discrepancies by training differential decoders, and then learn from the differential features iteratively. We evaluate LeFeD against eight state-of-the-art (SOTA) methods on three public datasets. Experiments show LeFeD surpasses competitors without any bells and whistles, such as uncertainty estimation and strong constraints, as well as setting a new state of the art for semi-supervised medical image segmentation. Code has been released at https://github.com/maxwell0027/LeFeD.

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一致性指导的差分解码用于增强半监督医学图像分割。
半监督学习(SSL)已被证明有利于缓解标记数据有限的问题,尤其是在体积医学图像分割方面。与以往侧重于探索高可信度伪标签或开发一致性正则化方案的半监督学习方法不同,我们的实证研究结果表明,当两个解码器努力生成一致的预测时,差异解码器特征就会自然出现。基于这一观察结果,我们首先分析了在伪标签和一致性正则化设置下,差异在学习一致性过程中的重要性,随后提出了一种名为 LeFeD 的新型 SSL 方法,该方法可学习两个解码器获得的特征级差异,并将这些信息作为反馈信号反馈给编码器。LeFeD 的核心设计是通过训练差异解码器来扩大差异,然后从差异特征中迭代学习。我们在三个公共数据集上对 LeFeD 与八种最先进(SOTA)方法进行了评估。实验结果表明,LeFeD 在没有不确定性估计和强约束等任何附加功能的情况下就超越了竞争对手,并为半监督医学影像分割技术开创了新局面。代码已发布于 https://github.com/maxwell0027/LeFeD。
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