Deep Learning Methods to Reveal Important X-ray Features in COVID-19 Detection: Investigation of Explainability and Feature Reproducibility

IF 0.8 Q3 MEDICINE, GENERAL & INTERNAL
Ioannis D. Apostolopoulos, D. Apostolopoulos, N. Papathanasiou
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引用次数: 3

Abstract

X-ray technology has been recently employed for the detection of the lethal human coronavirus disease 2019 (COVID-19) as a timely, cheap, and helpful ancillary method for diagnosis. The scientific community evaluated deep learning methods to aid in the automatic detection of the disease, utilizing publicly available small samples of X-ray images. In the majority of cases, the results demonstrate the effectiveness of deep learning and suggest valid detection of the disease from X-ray scans. However, little has been investigated regarding the actual findings of deep learning through the image process. In the present study, a large-scale dataset of pulmonary diseases, including COVID-19, was utilized for experiments, aiming to shed light on this issue. For the detection task, MobileNet (v2) was employed, which has been proven very effective in our previous works. Through analytical experiments utilizing feature visualization techniques and altering the input dataset classes, it was suggested that MobileNet (v2) discovers important image findings and not only features. It was demonstrated that MobileNet (v2) is an effective, accurate, and low-computational-cost solution for distinguishing COVID-19 from 12 various other pulmonary abnormalities and normal subjects. This study offers an analysis of image features extracted from MobileNet (v2), aiming to investigate the validity of those features and their medical importance. The pipeline can detect abnormal X-rays with an accuracy of 95.45 ± 1.54% and can distinguish COVID-19 with an accuracy of 89.88 ± 3.66%. The visualized results of the Grad-CAM algorithm provide evidence that the methodology identifies meaningful areas on the images. Finally, the detected image features were reproducible in 98% of the times after repeating the experiment for three times.
揭示COVID-19检测中重要x射线特征的深度学习方法:可解释性和特征再现性的研究
X射线技术最近被用于检测致命的2019年人类冠状病毒疾病(新冠肺炎),作为一种及时、廉价和有用的辅助诊断方法。科学界利用公开的X射线图像小样本,评估了有助于自动检测疾病的深度学习方法。在大多数情况下,研究结果证明了深度学习的有效性,并表明通过X射线扫描可以有效检测疾病。然而,关于通过图像处理进行深度学习的实际发现,很少有研究。在本研究中,利用包括新冠肺炎在内的肺部疾病的大规模数据集进行实验,旨在阐明这一问题。对于检测任务,采用了MobileNet(v2),这在我们之前的工作中已经被证明是非常有效的。通过利用特征可视化技术和改变输入数据集类别的分析实验,表明MobileNet(v2)发现了重要的图像发现,而不仅仅是特征。研究表明,MobileNet(v2)是一种有效、准确和低计算成本的解决方案,用于区分新冠肺炎与12种其他肺部异常和正常受试者。本研究对从MobileNet(v2)中提取的图像特征进行了分析,旨在调查这些特征的有效性及其医学重要性。该管道可以检测异常X射线,准确率为95.45±1.54%,可以区分新冠肺炎,准确度为89.88±3.66%。Grad-CAM算法的可视化结果提供了证据,证明该方法识别了图像上有意义的区域。最后,在重复实验三次后,检测到的图像特征在98%的时间内是可重复的。
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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