Hesam Hashemian, Tunde Peto, Renato Ambrósio, Imre Lengyel, Rahele Kafieh, Ahmed Muhammed Noori, Masoud Khorrami-Nejad
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引用次数: 0
Abstract
Artificial intelligence (AI) holds immense promise for transforming ophthalmic care through automated screening, precision diagnostics, and optimized treatment planning. This paper reviews recent advances and challenges in applying AI techniques such as machine learning and deep learning to major eye diseases. In diabetic retinopathy, AI algorithms analyze retinal images to accurately identify lesions, which helps clinicians in ophthalmology practice. Systems like IDx-DR (IDx Technologies Inc, USA) are FDA-approved for autonomous detection of referable diabetic retinopathy. For glaucoma, deep learning models assess optic nerve head morphology in fundus photographs to detect damage. In age-related macular degeneration, AI can quantify drusen and diagnose disease severity from both color fundus and optical coherence tomography images. AI has also been used in screening for retinopathy of prematurity, keratoconus, and dry eye disease. Beyond screening, AI can aid treatment decisions by forecasting disease progression and anti-VEGF response. However, potential limitations such as the quality and diversity of training data, lack of rigorous clinical validation, and challenges in regulatory approval and clinician trust must be addressed for the widespread adoption of AI. Two other significant hurdles include the integration of AI into existing clinical workflows and ensuring transparency in AI decision-making processes. With continued research to address these limitations, AI promises to enable earlier diagnosis, optimized resource allocation, personalized treatment, and improved patient outcomes. Besides, synergistic human-AI systems could set a new standard for evidence-based, precise ophthalmic care.
人工智能(AI)通过自动筛查、精确诊断和优化治疗计划,为改变眼科护理带来了巨大希望。本文回顾了将机器学习和深度学习等人工智能技术应用于主要眼科疾病的最新进展和挑战。在糖尿病视网膜病变方面,人工智能算法通过分析视网膜图像来准确识别病变,从而帮助临床医生开展眼科实践。IDx-DR(IDx Technologies Inc,美国)等系统已获得 FDA 批准,用于自主检测可转诊的糖尿病视网膜病变。对于青光眼,深度学习模型可评估眼底照片中的视神经头形态,以检测损伤情况。在老年性黄斑变性方面,人工智能可以从彩色眼底和光学相干断层扫描图像中量化色素沉着并诊断疾病的严重程度。人工智能还被用于筛查早产儿视网膜病变、角膜炎和干眼症。除筛查外,人工智能还能通过预测疾病进展和抗血管内皮生长因子反应来辅助治疗决策。然而,要广泛采用人工智能,必须解决潜在的局限性问题,如训练数据的质量和多样性、缺乏严格的临床验证以及监管审批和临床医生信任方面的挑战。另外两个重大障碍包括将人工智能整合到现有的临床工作流程中以及确保人工智能决策过程的透明度。通过持续研究解决这些限制因素,人工智能有望实现早期诊断、优化资源分配、个性化治疗和改善患者预后。此外,人类与人工智能系统的协同作用可为循证、精确的眼科护理设定新标准。