POPAR: Patch Order Prediction and Appearance Recovery for Self-supervised Medical Image Analysis.

Jiaxuan Pang, Fatemeh Haghighi, DongAo Ma, Nahid Ul Islam, Mohammad Reza Hosseinzadeh Taher, Michael B Gotway, Jianming Liang
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Abstract

Vision transformer-based self-supervised learning (SSL) approaches have recently shown substantial success in learning visual representations from unannotated photographic images. However, their acceptance in medical imaging is still lukewarm, due to the significant discrepancy between medical and photographic images. Consequently, we propose POPAR (patch order prediction and appearance recovery), a novel vision transformer-based self-supervised learning framework for chest X-ray images. POPAR leverages the benefits of vision transformers and unique properties of medical imaging, aiming to simultaneously learn patch-wise high-level contextual features by correcting shuffled patch orders and fine-grained features by recovering patch appearance. We transfer POPAR pretrained models to diverse downstream tasks. The experiment results suggest that (1) POPAR outperforms state-of-the-art (SoTA) self-supervised models with vision transformer backbone; (2) POPAR achieves significantly better performance over all three SoTA contrastive learning methods; and (3) POPAR also outperforms fully-supervised pretrained models across architectures. In addition, our ablation study suggests that to achieve better performance on medical imaging tasks, both fine-grained and global contextual features are preferred. All code and models are available at GitHub.com/JLiangLab/POPAR.

POPAR:用于自我监督医学图像分析的斑块阶次预测和外观恢复。
基于视觉变换器的自监督学习(SSL)方法最近在从无标注的摄影图像中学习视觉表征方面取得了巨大成功。然而,由于医学图像和摄影图像之间存在巨大差异,它们在医学成像中的应用仍然不温不火。因此,我们提出了 POPAR(补丁顺序预测和外观恢复),这是一种基于视觉变换器的新型胸部 X 光图像自监督学习框架。POPAR 充分利用了视觉变换器的优势和医学影像的独特属性,旨在通过校正洗牌补丁顺序来同时学习补丁的高级上下文特征,并通过恢复补丁外观来同时学习细粒度特征。我们将 POPAR 预训练模型应用于各种下游任务。实验结果表明:(1) POPAR 优于采用视觉转换器骨干的最先进(SoTA)自监督模型;(2) POPAR 的性能明显优于所有三种 SoTA 对比学习方法;(3) POPAR 还优于跨架构的全监督预训练模型。此外,我们的消融研究表明,要在医学成像任务中取得更好的性能,细粒度和全局上下文特征都是首选。所有代码和模型均可从 GitHub.com/JLiangLab/POPAR 获取。
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