基于光学相干断层扫描的深度学习模型,用于对正常及年龄相关性黄斑变性以及渗出性和非渗出性年龄相关性黄斑变性变化进行分类
Optical Coherence Tomography-Based Deep-Learning Models for Classifying Normal and Age-Related Macular Degeneration and Exudative and Non-Exudative Age-Related Macular Degeneration Changes.
作者信息
Motozawa Naohiro, An Guangzhou, Takagi Seiji, Kitahata Shohei, Mandai Michiko, Hirami Yasuhiko, Yokota Hideo, Akiba Masahiro, Tsujikawa Akitaka, Takahashi Masayo, Kurimoto Yasuo
机构信息
Department of Ophthalmology, Kobe City Eye Hospital, Kobe, Japan.
Laboratory for Retinal Regeneration, RIKEN Center for Biosystems Dynamics Research, Kobe, Japan.
出版信息
Ophthalmol Ther. 2019 Dec;8(4):527-539. doi: 10.1007/s40123-019-00207-y. Epub 2019 Aug 12.
INTRODUCTION
The use of optical coherence tomography (OCT) images is increasing in the medical treatment of age-related macular degeneration (AMD), and thus, the amount of data requiring analysis is increasing. Advances in machine-learning techniques may facilitate processing of large amounts of medical image data. Among deep-learning methods, convolution neural networks (CNNs) show superior image recognition ability. This study aimed to build deep-learning models that could distinguish AMD from healthy OCT scans and to distinguish AMD with and without exudative changes without using a segmentation algorithm.
METHODS
This was a cross-sectional observational clinical study. A total of 1621 spectral domain (SD)-OCT images of patients with AMD and a healthy control group were studied. The first CNN model was trained and validated using 1382 AMD images and 239 normal images. The second transfer-learning model was trained and validated with 721 AMD images with exudative changes and 661 AMD images without any exudate. The attention area of the CNN was described as a heat map by class activation mapping (CAM). In the second model, which classified images into AMD with or without exudative changes, we compared the learning stabilization of models using or not using transfer learning.
RESULTS
Using the first CNN model, we could classify AMD and normal OCT images with 100% sensitivity, 91.8% specificity, and 99.0% accuracy. In the second, transfer-learning model, we could classify AMD as having or not having exudative changes, with 98.4% sensitivity, 88.3% specificity, and 93.9% accuracy. CAM successfully described the heat-map area on the OCT images. Including the transfer-learning model in the second model resulted in faster stabilization than when the transfer-learning model was not included.
CONCLUSION
Two computational deep-learning models were developed and evaluated here; both models showed good performance. Automation of the interpretation process by using deep-learning models can save time and improve efficiency.
TRIAL REGISTRATION
No15073.
引言
光学相干断层扫描(OCT)图像在年龄相关性黄斑变性(AMD)的医学治疗中的应用日益增加,因此,需要分析的数据量也在不断增加。机器学习技术的进步可能有助于处理大量医学图像数据。在深度学习方法中,卷积神经网络(CNN)显示出卓越的图像识别能力。本研究旨在构建深度学习模型,以在不使用分割算法的情况下,将AMD与健康的OCT扫描区分开来,并区分有无渗出性改变的AMD。
方法
这是一项横断面观察性临床研究。共研究了1621例AMD患者和健康对照组的光谱域(SD)-OCT图像。第一个CNN模型使用1382张AMD图像和239张正常图像进行训练和验证。第二个迁移学习模型使用721张有渗出性改变的AMD图像和661张无任何渗出物的AMD图像进行训练和验证。通过类激活映射(CAM)将CNN的关注区域描述为热图。在将图像分为有或无渗出性改变的AMD的第二个模型中,我们比较了使用或不使用迁移学习的模型的学习稳定性。
结果
使用第一个CNN模型,我们能够以100%的灵敏度、91.8%的特异性和99.0%的准确率对AMD和正常OCT图像进行分类。在第二个迁移学习模型中,我们能够以98.4%的灵敏度、88.3%的特异性和93.9%的准确率将AMD分为有或无渗出性改变。CAM成功地描述了OCT图像上的热图区域。在第二个模型中纳入迁移学习模型比不纳入迁移学习模型能更快地实现稳定。
结论
本研究开发并评估了两种计算深度学习模型;两种模型均表现出良好的性能。使用深度学习模型实现解释过程的自动化可以节省时间并提高效率。
试验注册
No15073
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