{"title":"Diabetic retinopathy screening through artificial intelligence algorithms: A systematic review","authors":"","doi":"10.1016/j.survophthal.2024.05.008","DOIUrl":null,"url":null,"abstract":"<div><p>Diabetic retinopathy (DR) poses a significant challenge in diabetes management, with its progression often asymptomatic until advanced stages. This underscores the urgent need for cost-effective and reliable screening methods. Consequently, the integration of artificial intelligence (AI) tools presents a promising avenue to address this need effectively. We provide an overview of the current state of the art results and techniques in DR screening using AI, while also identifying gaps in research for future exploration. By synthesizing existing database and pinpointing areas requiring further investigation, this paper seeks to guide the direction of future research in the field of automatic diabetic retinopathy screening. There has been a continuous rise in the number of articles detailing deep learning (DL) methods designed for the automatic screening of diabetic retinopathy especially by the year 2021. Researchers utilized various databases, with a primary focus on the IDRiD dataset. This dataset consists of color fundus images captured at an ophthalmological clinic situated in India. It comprises 516 images that depict various stages of DR and diabetic macular edema. Each of the chosen papers concentrates on various DR signs. Nevertheless, a significant portion primarily focused on detecting exudates, which remains insufficient to assess the overall presence of this disease. Various AI methods have been employed to identify DR signs. Among the chosen papers, 4.7 % utilized detection methods, 46.5 % employed classification techniques, 41.9 % relied on segmentation, and 7 % opted for a combination of classification and segmentation. Metrics calculated from 80 % of the articles employing preprocessing techniques demonstrated the significant benefits of this approach in enhancing results quality. In addition, multiple DL techniques, starting by classification, detection then segmentation. Researchers used mostly YOLO for detection, ViT for classification, and U-Net for segmentation. Another perspective on the evolving landscape of AI models for diabetic retinopathy screening lies in the increasing adoption of Convolutional Neural Networks for classification tasks and U-Net architectures for segmentation purposes; however, there is a growing realization within the research community that these techniques, while powerful individually, can be even more effective when integrated. This integration holds promise for not only diagnosing DR, but also accurately classifying its different stages, thereby enabling more tailored treatment strategies. Despite this potential, the development of AI models for DR screening is fraught with challenges. Chief among these is the difficulty in obtaining the high-quality, labeled data necessary for training models to perform effectively. This scarcity of data poses significant barriers to achieving robust performance and can hinder progress in developing accurate screening systems. Moreover, managing the complexity of these models, particularly deep neural networks, presents its own set of challenges. Additionally, interpreting the outputs of these models and ensuring their reliability in real-world clinical settings remain ongoing concerns. Furthermore, the iterative process of training and adapting these models to specific datasets can be time-consuming and resource-intensive. These challenges underscore the multifaceted nature of developing effective AI models for DR screening. Addressing these obstacles requires concerted efforts from researchers, clinicians, and technologists to develop new approaches and overcome existing limitations. By doing so, a full potential of AI may transform DR screening and improve patient outcomes.</p></div>","PeriodicalId":22102,"journal":{"name":"Survey of ophthalmology","volume":null,"pages":null},"PeriodicalIF":5.1000,"publicationDate":"2024-09-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Survey of ophthalmology","FirstCategoryId":"3","ListUrlMain":"https://www.sciencedirect.com/science/article/pii/S0039625724000511","RegionNum":2,"RegionCategory":"医学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q1","JCRName":"OPHTHALMOLOGY","Score":null,"Total":0}
引用次数: 0
Abstract
Diabetic retinopathy (DR) poses a significant challenge in diabetes management, with its progression often asymptomatic until advanced stages. This underscores the urgent need for cost-effective and reliable screening methods. Consequently, the integration of artificial intelligence (AI) tools presents a promising avenue to address this need effectively. We provide an overview of the current state of the art results and techniques in DR screening using AI, while also identifying gaps in research for future exploration. By synthesizing existing database and pinpointing areas requiring further investigation, this paper seeks to guide the direction of future research in the field of automatic diabetic retinopathy screening. There has been a continuous rise in the number of articles detailing deep learning (DL) methods designed for the automatic screening of diabetic retinopathy especially by the year 2021. Researchers utilized various databases, with a primary focus on the IDRiD dataset. This dataset consists of color fundus images captured at an ophthalmological clinic situated in India. It comprises 516 images that depict various stages of DR and diabetic macular edema. Each of the chosen papers concentrates on various DR signs. Nevertheless, a significant portion primarily focused on detecting exudates, which remains insufficient to assess the overall presence of this disease. Various AI methods have been employed to identify DR signs. Among the chosen papers, 4.7 % utilized detection methods, 46.5 % employed classification techniques, 41.9 % relied on segmentation, and 7 % opted for a combination of classification and segmentation. Metrics calculated from 80 % of the articles employing preprocessing techniques demonstrated the significant benefits of this approach in enhancing results quality. In addition, multiple DL techniques, starting by classification, detection then segmentation. Researchers used mostly YOLO for detection, ViT for classification, and U-Net for segmentation. Another perspective on the evolving landscape of AI models for diabetic retinopathy screening lies in the increasing adoption of Convolutional Neural Networks for classification tasks and U-Net architectures for segmentation purposes; however, there is a growing realization within the research community that these techniques, while powerful individually, can be even more effective when integrated. This integration holds promise for not only diagnosing DR, but also accurately classifying its different stages, thereby enabling more tailored treatment strategies. Despite this potential, the development of AI models for DR screening is fraught with challenges. Chief among these is the difficulty in obtaining the high-quality, labeled data necessary for training models to perform effectively. This scarcity of data poses significant barriers to achieving robust performance and can hinder progress in developing accurate screening systems. Moreover, managing the complexity of these models, particularly deep neural networks, presents its own set of challenges. Additionally, interpreting the outputs of these models and ensuring their reliability in real-world clinical settings remain ongoing concerns. Furthermore, the iterative process of training and adapting these models to specific datasets can be time-consuming and resource-intensive. These challenges underscore the multifaceted nature of developing effective AI models for DR screening. Addressing these obstacles requires concerted efforts from researchers, clinicians, and technologists to develop new approaches and overcome existing limitations. By doing so, a full potential of AI may transform DR screening and improve patient outcomes.
糖尿病视网膜病变(DR)是糖尿病管理中的一项重大挑战,其进展直到晚期通常都没有症状。这凸显了对具有成本效益且可靠的筛查方法的迫切需求。因此,人工智能(AI)工具的整合为有效满足这一需求提供了一条大有可为的途径。我们概述了目前利用人工智能进行 DR 筛查的最新成果和技术,同时也指出了有待未来探索的研究空白。通过综合现有数据库并指出需要进一步研究的领域,本文试图为糖尿病视网膜病变自动筛查领域的未来研究指明方向。关于深度学习(DL)方法设计用于糖尿病视网膜病变自动筛查的文章数量持续上升,尤其是到 2021 年。研究人员利用了各种数据库,主要侧重于 IDRiD 数据集。该数据集由印度一家眼科诊所采集的彩色眼底图像组成。它包括 516 幅描绘 DR 和糖尿病黄斑水肿不同阶段的图像。所选的每篇论文都集中讨论了各种 DR 征兆。然而,有相当一部分论文主要侧重于检测渗出物,这仍然不足以评估这种疾病的总体存在情况。各种人工智能方法已被用于识别 DR 征兆。在所选论文中,4.7%采用了检测方法,46.5%采用了分类技术,41.9%依赖于分割,7%选择了分类和分割相结合的方法。从 80% 采用预处理技术的文章中计算出的指标表明,这种方法在提高结果质量方面具有显著优势。此外,还有多种 DL 技术,首先是分类,然后是检测,最后是分割。研究人员主要使用 YOLO 进行检测,使用 ViT 进行分类,使用 U-Net 进行分割。从另一个角度看糖尿病视网膜病变筛查人工智能模型的发展,就是越来越多地采用卷积神经网络来完成分类任务,并采用 U-Net 架构来进行分割。这种整合不仅有望诊断 DR,还能对其不同阶段进行准确分类,从而制定更有针对性的治疗策略。尽管存在这种潜力,但开发用于 DR 筛查的人工智能模型仍充满挑战。其中最主要的挑战是难以获得训练模型有效运行所需的高质量标注数据。数据的匮乏对实现强大的性能构成了重大障碍,并可能阻碍准确筛查系统的开发进度。此外,管理这些模型(尤其是深度神经网络)的复杂性也带来了一系列挑战。此外,解释这些模型的输出结果并确保其在实际临床环境中的可靠性,仍然是人们一直关注的问题。此外,根据特定数据集训练和调整这些模型的迭代过程可能会耗费大量时间和资源。这些挑战凸显了为 DR 筛查开发有效人工智能模型的多面性。要解决这些障碍,需要研究人员、临床医生和技术人员共同努力,开发新方法并克服现有限制。通过这些努力,人工智能的全部潜力可能会改变 DR 筛查并改善患者的预后。
期刊介绍:
Survey of Ophthalmology is a clinically oriented review journal designed to keep ophthalmologists up to date. Comprehensive major review articles, written by experts and stringently refereed, integrate the literature on subjects selected for their clinical importance. Survey also includes feature articles, section reviews, book reviews, and abstracts.