基于人工智能的视网膜前膜诊断模型的性能：系统回顾和荟萃分析。

IF 4.1 1区医学 Q1 OPHTHALMOLOGY

American Journal of Ophthalmology Pub Date : 2025-05-31 DOI:10.1016/j.ajo.2025.05.041

David Mikhail , Angel Gao , Andrew Farah , Andrew Mihalache , Daniel Milad , Fares Antaki , Marko M. Popovic , Reut Shor , Renaud Duval , Peter J. Kertes , Radha P. Kohly , Rajeev H. Muni

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引用次数: 0

摘要

主题：视网膜前膜（ERM）可通过在视网膜内形成视网膜前纤维层而损害中央视力。基于人工智能（AI）的工具可以简化ERM诊断，但它们的整体性能和影响准确性的因素需要评估。临床相关性：随着人口老龄化，ERM患病率预计会上升，对临床资源的需求也会增加。通过人工智能模型进行早期检测，可以加快诊断速度，减少主观错误，并指导及时的手术干预。本系统综述和荟萃分析评估了人工智能模型用于检测ERM的综合诊断性能，并确定了影响其性能的研究和模型级因素。方法：在Medline、Embase、Cochrane Library、Web of Science和预印本数据库中进行综合检索，检索时间从成立到2024年6月。纳入的研究评估了人工智能模型对ERM的诊断。使用诊断准确性研究质量评估2 （QUADAS-2）工具评估研究质量和偏倚风险。随机效应模型应用于诊断准确性、敏感性、特异性和诊断优势比。亚组分析探讨了影响模型性能的因素。该研究方案已在国际前瞻性系统评价注册（PROSPERO - CRD42024563571）注册。结果：在筛选的379篇文章中，26篇符合纳入标准，19篇对meta分析有贡献。研究环境主要以医院为基础（76.9%），一些研究来自学术计算机和生物医学科学系（15.4%）和社区中心（7.7%）。质量评估表明95%的研究存在低偏倚风险或不明确的偏倚风险和适用性问题。合并敏感性为90.1% (95% CI: 85.8-93.2)，合并特异性为95.7% （95% CI: 88.8-95.2）。亚组分析显示，使用彩色眼底照片的AI模型的特异性（97.1%,95% CI: 96.0-97.9）高于光学相干断层扫描，后者的特异性为92.6% （95% CI: 88.8-95.2）。26.9%的研究进行了外部验证。所有纳入的研究均以专家人工评分为参考标准，其中25项（96.2%）基于与人工智能输入相同的成像方式。发展数据集中ERM病例的比例因研究而异，特别是在单一疾病和多类别模型之间。结论：人工智能模型对ERM具有较高的诊断性能。然而，人工智能开发方法中有限的外部验证和可变性限制了模型与现实世界适用性之间的直接比较。未来的工作应该标准化模型开发和报告实践，提高数据互操作性，并开发预测模型来跟踪疾病进展并确定最佳手术时机。

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Performance of Artificial Intelligence-Based Models for Epiretinal Membrane Diagnosis: A Systematic Review and Meta-Analysis

Topic

Epiretinal membrane (ERM) can impair central vision by forming a pre-retinal fibrous layer on the inner retina. Artificial intelligence (AI)–based tools may streamline ERM diagnosis, but their overall performance and factors affecting accuracy require evaluation.

Clinical Relevance

With an aging population, ERM prevalence is expected to rise, placing increased demands on clinical resources. Early detection via AI models could expedite diagnosis, reduce subjective errors, and guide timely surgical intervention. This systematic review and meta-analysis evaluates the pooled diagnostic performance of AI models for detecting ERM and identifies study- and model-level factors influencing their performance.

Design

Systematic review and meta-analysis.

Methods

Comprehensive searches were conducted in Medline, Embase, Cochrane Library, Web of Science, and preprint databases from inception to June 2024. Included studies evaluated AI models for ERM diagnosis. Study quality and risk of bias were assessed using the Quality Assessment for Diagnostic Accuracy Studies 2 (QUADAS-2) tool. A random-effects model was applied to pool diagnostic accuracy, sensitivity, specificity, and diagnostic odds ratio. Subgroup analyses explored factors affecting model performance. The study protocol was registered with the International Prospective Register of Systematic Reviews (PROSPERO - CRD42024563571).

Results

Of 379 articles screened, 26 met inclusion criteria, and 19 contributed to the meta-analysis. Study settings were predominantly hospital-based (76.9%), with some studies from academic computer and biomedical science departments (15.4%) and community centers (7.7%). Quality assessments suggested low or unclear risk of bias and applicability concerns in 95% of studies. The pooled sensitivity was 90.1% (95% CI: 85.8-93.2), and the pooled specificity was 95.7% (95% CI: 88.8-95.2). Subgroup analysis showed higher specificity (97.1%, 95% CI: 96.0-97.9) in AI models using color fundus photographs than optical coherence tomography scans, which had a specificity of 92.6% (95% CI: 88.8-95.2). External validation was performed in 26.9% of studies. All included studies used expert human grading as the reference standard, of which 25 (96.2%) were based on the same imaging modality as the AI input. The proportion of ERM cases in development datasets varied across studies, particularly between single-disease and multiclass models.

Conclusions

AI models demonstrate high diagnostic performance for ERM. However, limited external validation and variability in AI development methodologies limits direct comparison between models and real-world applicability. Future work should standardize model development and reporting practices, improve data interoperability, and develop prediction models to track disease progression and determine optimal surgical timing.

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来源期刊

American Journal of Ophthalmology 医学-眼科学

CiteScore

9.20

自引率

7.10%

发文量

406

审稿时长

36 days

期刊介绍： The American Journal of Ophthalmology is a peer-reviewed, scientific publication that welcomes the submission of original, previously unpublished manuscripts directed to ophthalmologists and visual science specialists describing clinical investigations, clinical observations, and clinically relevant laboratory investigations. Published monthly since 1884, the full text of the American Journal of Ophthalmology and supplementary material are also presented online at www.AJO.com and on ScienceDirect. The American Journal of Ophthalmology publishes Full-Length Articles, Perspectives, Editorials, Correspondences, Books Reports and Announcements. Brief Reports and Case Reports are no longer published. We recommend submitting Brief Reports and Case Reports to our companion publication, the American Journal of Ophthalmology Case Reports. Manuscripts are accepted with the understanding that they have not been and will not be published elsewhere substantially in any format, and that there are no ethical problems with the content or data collection. Authors may be requested to produce the data upon which the manuscript is based and to answer expeditiously any questions about the manuscript or its authors.