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基于深度学习的皮肤损伤自动诊断方法。

Deep Learning-Based Methods for Automatic Diagnosis of Skin Lesions.

机构信息

Faculty of Automatic Control and Computers, University Politehnica of Bucharest, 060042 Bucharest, Romania.

出版信息

Sensors (Basel). 2020 Mar 21;20(6):1753. doi: 10.3390/s20061753.

DOI:10.3390/s20061753
PMID:32245258
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7147720/
Abstract

The main purpose of the study was to develop a high accuracy system able to diagnose skin lesions using deep learning-based methods. We propose a new decision system based on multiple classifiers like neural networks and feature-based methods. Each classifier (method) gives the final decision system a certain weight, depending on the calculated accuracy, helping the system make a better decision. First, we created a neural network (NN) that can differentiate melanoma from benign nevus. The NN architecture is analyzed by evaluating it during the training process. Some biostatistic parameters, such as accuracy, specificity, sensitivity, and Dice coefficient are calculated. Then, we developed three other methods based on convolutional neural networks (CNNs). The CNNs were pre-trained using large ImageNet and Places365 databases. GoogleNet, ResNet-101, and NasNet-Large, were used in the enumeration order. CNN architectures were fine-tuned in order to distinguish the different types of skin lesions using transfer learning. The accuracies of the classifications were determined. The last proposed method uses the classical method of image object detection, more precisely, the one in which some features are extracted from the images, followed by the classification step. In this case, the classification was done by using a support vector machine. Just as in the first method, the sensitivity, specificity, Dice similarity coefficient and accuracy are determined. A comparison of the obtained results from all the methods is then done. As mentioned above, the novelty of this paper is the integration of these methods in a global fusion-based decision system that uses the results obtained by each individual method to establish the fusion weights. The results obtained by carrying out the experiments on two different free databases shows that the proposed system offers higher accuracy results.

摘要

本研究的主要目的是开发一种能够使用基于深度学习的方法诊断皮肤病变的高精度系统。我们提出了一种新的决策系统,该系统基于神经网络和基于特征的方法等多种分类器。每个分类器(方法)根据计算出的准确性为最终决策系统赋予一定的权重,帮助系统做出更好的决策。首先,我们创建了一个可以区分黑色素瘤和良性痣的神经网络(NN)。通过在训练过程中评估 NN 架构来分析其架构。计算了一些生物统计参数,如准确性、特异性、敏感性和 Dice 系数。然后,我们基于卷积神经网络(CNN)开发了另外三种方法。使用大型 ImageNet 和 Places365 数据库对 CNN 进行预训练。按枚举顺序使用了 GoogleNet、ResNet-101 和 NasNet-Large。使用迁移学习对 CNN 架构进行微调,以区分不同类型的皮肤病变。确定了分类的准确性。最后提出的方法使用了经典的图像对象检测方法,更确切地说,是从图像中提取一些特征,然后进行分类步骤。在这种情况下,分类是通过使用支持向量机完成的。与第一种方法一样,确定了敏感性、特异性、Dice 相似系数和准确性。然后对所有方法的结果进行比较。如上所述,本文的新颖之处在于将这些方法集成到一个基于全局融合的决策系统中,该系统使用每个单独方法获得的结果来建立融合权重。在两个不同的免费数据库上进行实验所获得的结果表明,所提出的系统提供了更高的准确性结果。

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