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基于 DenseNet 架构的语义实例分割的高血压性视网膜病变五阶段自动检测与分类系统。

An Automatic Detection and Classification System of Five Stages for Hypertensive Retinopathy Using Semantic and Instance Segmentation in DenseNet Architecture.

机构信息

College of Computer and Information Sciences, Imam Mohammad Ibn Saud Islamic University (IMSIU), Riyadh 11432, Saudi Arabia.

Department of Computer Software Engineering, Military College of Signals, National University of Sciences and Technology (MCS-NUST), Islamabad 44000, Pakistan.

出版信息

Sensors (Basel). 2021 Oct 19;21(20):6936. doi: 10.3390/s21206936.

DOI:10.3390/s21206936
PMID:34696149
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8538561/
Abstract

The stage and duration of hypertension are connected to the occurrence of Hypertensive Retinopathy (HR) of eye disease. Currently, a few computerized systems have been developed to recognize HR by using only two stages. It is difficult to define specialized features to recognize five grades of HR. In addition, deep features have been used in the past, but the classification accuracy is not up-to-the-mark. In this research, a new hypertensive retinopathy (HYPER-RETINO) framework is developed to grade the HR based on five grades. The HYPER-RETINO system is implemented based on pre-trained HR-related lesions. To develop this HYPER-RETINO system, several steps are implemented such as a preprocessing, the detection of HR-related lesions by semantic and instance-based segmentation and a DenseNet architecture to classify the stages of HR. Overall, the HYPER-RETINO system determined the local regions within input retinal fundus images to recognize five grades of HR. On average, a 10-fold cross-validation test obtained sensitivity (SE) of 90.5%, specificity (SP) of 91.5%, accuracy (ACC) of 92.6%, precision (PR) of 91.7%, Matthews correlation coefficient (MCC) of 61%, F1-score of 92% and area-under-the-curve (AUC) of 0.915 on 1400 HR images. Thus, the applicability of the HYPER-RETINO method to reliably diagnose stages of HR is verified by experimental findings.

摘要

高血压的阶段和持续时间与眼部疾病的高血压性视网膜病变(HR)的发生有关。目前,已经开发出了一些使用仅两个阶段的计算机系统来识别 HR。很难定义专门的特征来识别 HR 的五个等级。此外,过去已经使用了深度特征,但分类准确性不尽如人意。在这项研究中,开发了一种新的高血压性视网膜病变(HYPER-RETINO)框架,用于根据五个等级对 HR 进行分级。HYPER-RETINO 系统是基于与 HR 相关的病变的预训练来实现的。为了开发这个 HYPER-RETINO 系统,实施了几个步骤,例如预处理、基于语义和实例的 HR 相关病变检测以及 DenseNet 架构来对 HR 阶段进行分类。总的来说,HYPER-RETINO 系统确定了输入视网膜眼底图像中的局部区域,以识别 HR 的五个等级。平均而言,在 1400 张 HR 图像上进行的 10 倍交叉验证测试获得了 90.5%的敏感性(SE)、91.5%的特异性(SP)、92.6%的准确性(ACC)、91.7%的精度(PR)、61%的马修斯相关系数(MCC)、92%的 F1 分数和 0.915 的曲线下面积(AUC)。因此,实验结果验证了 HYPER-RETINO 方法在可靠诊断 HR 阶段方面的适用性。

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