Attend Who is Weak: Pruning-assisted Medical Image Localization under Sophisticated and Implicit Imbalances.

Ajay Jaiswal, Tianlong Chen, Justin F Rousseau, Yifan Peng, Ying Ding, Zhangyang Wang
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引用次数: 5

Abstract

Deep neural networks (DNNs) have rapidly become a de facto choice for medical image understanding tasks. However, DNNs are notoriously fragile to the class imbalance in image classification. We further point out that such imbalance fragility can be amplified when it comes to more sophisticated tasks such as pathology localization, as imbalances in such problems can have highly complex and often implicit forms of presence. For example, different pathology can have different sizes or colors (w.r.t.the background), different underlying demographic distributions, and in general different difficulty levels to recognize, even in a meticulously curated balanced distribution of training data. In this paper, we propose to use pruning to automatically and adaptively identify hard-to-learn (HTL) training samples, and improve pathology localization by attending them explicitly, during training in supervised, semi-supervised, and weakly-supervised settings. Our main inspiration is drawn from the recent finding that deep classification models have difficult-to-memorize samples and those may be effectively exposed through network pruning [15] - and we extend such observation beyond classification for the first time. We also present an interesting demographic analysis which illustrates HTLs ability to capture complex demographic imbalances. Our extensive experiments on the Skin Lesion Localization task in multiple training settings by paying additional attention to HTLs show significant improvement of localization performance by ~2-3%.

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关注谁是弱者:复杂和隐式失衡下的剪枝辅助医学图像定位。
深度神经网络(dnn)已迅速成为医学图像理解任务的实际选择。然而,dnn在图像分类中极易受到类别不平衡的影响。我们进一步指出,当涉及到更复杂的任务(如病理定位)时,这种不平衡的脆弱性可能会被放大,因为这些问题中的不平衡可能具有高度复杂且通常隐含的存在形式。例如,不同的病理可以有不同的大小或颜色(w.r.t背景),不同的潜在人口分布,以及通常不同的识别难度,即使在精心策划的训练数据平衡分布中也是如此。在本文中,我们建议使用修剪来自动和自适应地识别难学习(html)训练样本,并通过在监督、半监督和弱监督设置的训练中明确地参与它们来提高病理定位。我们的主要灵感来自最近的一项发现,即深度分类模型具有难以记忆的样本,这些样本可以通过网络修剪有效地暴露出来[15],并且我们首次将这种观察扩展到分类之外。我们还提供了一个有趣的人口统计分析,说明了html捕捉复杂人口失衡的能力。我们在多个训练环境下对皮肤病变定位任务进行了广泛的实验,通过额外关注html,我们的定位性能显著提高了~2-3%。
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