Brainomaly: Unsupervised Neurologic Disease Detection Utilizing Unannotated T1-weighted Brain MR Images.

Md Mahfuzur Rahman Siddiquee, Jay Shah, Teresa Wu, Catherine Chong, Todd J Schwedt, Gina Dumkrieger, Simona Nikolova, Baoxin Li
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Abstract

Harnessing the power of deep neural networks in the medical imaging domain is challenging due to the difficulties in acquiring large annotated datasets, especially for rare diseases, which involve high costs, time, and effort for annotation. Unsupervised disease detection methods, such as anomaly detection, can significantly reduce human effort in these scenarios. While anomaly detection typically focuses on learning from images of healthy subjects only, real-world situations often present unannotated datasets with a mixture of healthy and diseased subjects. Recent studies have demonstrated that utilizing such unannotated images can improve unsupervised disease and anomaly detection. However, these methods do not utilize knowledge specific to registered neuroimages, resulting in a subpar performance in neurologic disease detection. To address this limitation, we propose Brainomaly, a GAN-based image-to-image translation method specifically designed for neurologic disease detection. Brainomaly not only offers tailored image-to-image translation suitable for neuroimages but also leverages unannotated mixed images to achieve superior neurologic disease detection. Additionally, we address the issue of model selection for inference without annotated samples by proposing a pseudo-AUC metric, further enhancing Brainomaly's detection performance. Extensive experiments and ablation studies demonstrate that Brainomaly outperforms existing state-of-the-art unsupervised disease and anomaly detection methods by significant margins in Alzheimer's disease detection using a publicly available dataset and headache detection using an institutional dataset. The code is available from https://github.com/mahfuzmohammad/Brainomaly.

脑异常:利用未标注的 T1 加权脑 MR 图像进行无监督神经系统疾病检测
在医学影像领域利用深度神经网络的威力具有挑战性,因为很难获得大型注释数据集,特别是罕见疾病,这涉及高成本、时间和注释工作。无监督疾病检测方法(如异常检测)可以大大减少这些场景中的人力投入。异常检测通常只侧重于从健康受试者的图像中学习,而现实世界中经常出现健康受试者和患病受试者混合的未标注数据集。最近的研究表明,利用这类未标注的图像可以改进无监督疾病和异常检测。然而,这些方法并没有利用注册神经图像的特定知识,因此在神经疾病检测方面表现不佳。为了解决这一局限性,我们提出了 Brainomaly,一种基于 GAN 的图像到图像转换方法,专门用于神经疾病检测。Brainomaly 不仅能提供适合神经图像的定制图像到图像转换,还能利用未标注的混合图像实现出色的神经疾病检测。此外,我们还通过提出一种伪 AUC 指标,解决了无注释样本推断的模型选择问题,进一步提高了 Brainomaly 的检测性能。广泛的实验和消融研究表明,在使用公开数据集检测阿尔茨海默病和使用机构数据集检测头痛方面,Brainomaly 的性能明显优于现有的最先进的无监督疾病和异常检测方法。代码可从 https://github.com/mahfuzmohammad/Brainomaly 获取。
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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