Performance Improvement of Automated Melanoma Diagnosis System by Data Augmentation

IF 0.8 Q4 ENGINEERING, BIOMEDICAL
Kana Kato, M. Nemoto, Yuichi Kimura, Y. Kiyohara, H. Koga, N. Yamazaki, G. Christensen, C. Ingvar, K. Nielsen, A. Nakamura, T. Sota, T. Nagaoka
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引用次数: 5

Abstract

Color information is an important tool for diagnosing melanoma. In this study, we used a hyper-spectral imager (HSI), which can measure color information in detail, to develop an automated melanoma diagnosis system. In recent years, the effectiveness of deep learning has become more widely accepted in the field of image recognition. We therefore integrated the deep convolutional neural network with transfer learning into our system. We tried data augmentation to demonstrate how our system improves diagnostic performance. 283 melanoma lesions and 336 non-melanoma lesions were used for the analysis. The data measured by HSI, called the hyperspectral data (HSD), were converted to a single-wavelength image averaged over plus or minus 3 nm. We used GoogLeNet which was pre-trained by ImageNet and then was transferred to analyze the HSD. In the transfer learning, we used not only the original HSD but also artificial augmentation dataset to improve the melanoma classification performance of GoogLeNet. Since GoogLeNet requires three-channel images as input, three wavelengths were selected from those single-wavelength images and assigned to three channels in wavelength order from short to long. The sensitivity and specificity of our system were estimated by 5-fold cross-val-idation. The results of a combination of 530, 560, and 590 nm (combination A) and 500, 620, and 740 nm (com-bination B) were compared. We also compared the diagnostic performance with and without the data augmentation. All images were augmented by inverting the image vertically and/or horizontally. Without data augmentation, the respective sensitivity and specificity of our system were 77.4% and 75.6% for combination A and 73.1% and 80.6% for combination B. With data augmentation, these numbers improved to 79.9% and 82.4% for combination A and 76.7% and 82.2% for combination B. From these results, we conclude that the diagnostic performance of our system has been improved by data augmentation. Furthermore, our system suc-ceeds to differentiate melanoma with a sensitivity of almost 80%. (Less)
基于数据增强的黑色素瘤自动诊断系统性能改进
颜色信息是诊断黑色素瘤的重要工具。在本研究中,我们使用可以详细测量颜色信息的超光谱成像仪(HSI)来开发黑色素瘤自动诊断系统。近年来,深度学习的有效性在图像识别领域得到了越来越广泛的认可。因此,我们将深度卷积神经网络与迁移学习集成到我们的系统中。我们尝试了数据增强来演示我们的系统如何提高诊断性能。283个黑色素瘤病变和336个非黑色素瘤病变用于分析。HSI测量的数据被称为高光谱数据(HSD),被转换成平均在正负3nm的单波长图像。我们使用经过ImageNet预训练的GoogLeNet进行HSD分析。在迁移学习中,我们不仅使用原始的HSD数据集,还使用人工增强数据集来提高GoogLeNet的黑色素瘤分类性能。由于GoogLeNet需要三通道图像作为输入,因此从这些单波长图像中选择三个波长,并按照波长由短到长的顺序分配给三个通道。我们的系统的敏感性和特异性通过5倍交叉验证估计。比较530、560和590 nm(组合a)和500、620和740 nm(组合B)的组合结果。我们还比较了有数据增强和没有数据增强的诊断性能。所有图像都通过垂直和/或水平反转图像来增强。在没有数据增强的情况下,我们的系统对组合A的敏感性和特异性分别为77.4%和75.6%,对组合b的敏感性和特异性分别为73.1%和80.6%。在数据增强的情况下,我们的系统对组合A的敏感性和特异性分别为79.9%和82.4%,对组合b的敏感性和特异性分别为76.7%和82.2%。此外,我们的系统成功区分黑色素瘤的敏感度几乎达到80%。(少)
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来源期刊
Advanced Biomedical Engineering
Advanced Biomedical Engineering ENGINEERING, BIOMEDICAL-
CiteScore
1.40
自引率
10.00%
发文量
15
审稿时长
15 weeks
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