Omar Shareef , Mohammad Soleimani , Elmer Tu , Deborah Jacobs , Joseph Ciolino , Amir Rahdar , Kasra Cheraqpour , Mohammadali Ashraf , Nabiha B. Habib , Jason Greenfield , Siamak Yousefi , Ali R. Djalilian , Hajirah N. Saeed
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Distinguishing between AK and NSF was designed as the task and completed through a devised convolutional neural network.</p></div><div><h3>Results</h3><p>A dataset of 3312 confocal images from 17 patients with a culture-confirmed diagnosis of AK was used in this study. The inter-rater agreement for identifying the presence or absence of AK in IVCM images was 84 %, corresponding to a total of 2782 images on which both observers agreed and which were included in the model. 1242 and 1265 images of AK and NSF, respectively, were utilized in the training and validation sets, and 173 and 102 images of AK and NSF, respectively, were utilized in the evaluation set. Our model had an accuracy, sensitivity, and specificity of 76 % each, and a precision of 78 %.</p></div><div><h3>Conclusions</h3><p>We developed an HRT-based IVCM AI model for AK diagnosis utilizing culture-confirmed cases of AK. 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引用次数: 0
摘要
目的:根据从海德堡视网膜断层成像仪 3(HRT 3)中提取的活体共聚焦显微镜(IVCM)图像,开发一种人工智能(AI)模型,用于诊断棘阿米巴角膜炎(AK):这项回顾性队列研究利用了 2013 年至 2021 年间马萨诸塞州眼耳科医院经培养确诊为 AK 患者的 IVCM 图像。两名角膜病专家以盲法独立将图像标记为 AK 或非特异性发现 (NSF)。然后通过 Python 和 TensorFlow 执行深度学习任务。区分 AK 和 NSF 被设计为一项任务,并通过设计的卷积神经网络完成:本研究使用了一个包含 3312 张共聚焦图像的数据集,这些图像来自 17 名经培养确诊为 AK 的患者。在 IVCM 图像中识别是否存在 AK 的评分者之间的一致率为 84%,共有 2,782 张图像的评分者之间达成一致并被纳入模型。训练集和验证集分别使用了 1,242 张和 1,265 张 AK 和 NSF 图像,评估集分别使用了 173 张和 102 张 AK 和 NSF 图像。我们模型的准确度、灵敏度和特异度分别为 76%,精确度为 78%:我们利用培养确诊的 AK 病例,开发了基于 HRT 的 IVCM AI 模型,用于诊断 AK。我们在诊断 AK 方面取得了很好的准确性,我们的模型在临床应用 AI 改善早期 AK 诊断方面前景广阔。
A novel artificial intelligence model for diagnosing Acanthamoeba keratitis through confocal microscopy
Purpose
To develop an artificial intelligence (AI) model to diagnose Acanthamoeba keratitis (AK) based on in vivo confocal microscopy (IVCM) images extracted from the Heidelberg Retinal Tomograph 3 (HRT 3).
Methods
This retrospective cohort study utilized HRT 3 IVCM images from patients who had received a culture-confirmed diagnosis of AK between 2013 and 2021 at Massachusetts Eye and Ear. Two cornea specialists independently labeled the images as AK or nonspecific finding (NSF) in a blind manner. Deep learning tasks were then conducted through Python and TensorFlow. Distinguishing between AK and NSF was designed as the task and completed through a devised convolutional neural network.
Results
A dataset of 3312 confocal images from 17 patients with a culture-confirmed diagnosis of AK was used in this study. The inter-rater agreement for identifying the presence or absence of AK in IVCM images was 84 %, corresponding to a total of 2782 images on which both observers agreed and which were included in the model. 1242 and 1265 images of AK and NSF, respectively, were utilized in the training and validation sets, and 173 and 102 images of AK and NSF, respectively, were utilized in the evaluation set. Our model had an accuracy, sensitivity, and specificity of 76 % each, and a precision of 78 %.
Conclusions
We developed an HRT-based IVCM AI model for AK diagnosis utilizing culture-confirmed cases of AK. We achieved good accuracy in diagnosing AK and our model holds significant promise in the clinical application of AI in improving early AK diagnosis.
期刊介绍:
The Ocular Surface, a quarterly, a peer-reviewed journal, is an authoritative resource that integrates and interprets major findings in diverse fields related to the ocular surface, including ophthalmology, optometry, genetics, molecular biology, pharmacology, immunology, infectious disease, and epidemiology. Its critical review articles cover the most current knowledge on medical and surgical management of ocular surface pathology, new understandings of ocular surface physiology, the meaning of recent discoveries on how the ocular surface responds to injury and disease, and updates on drug and device development. The journal also publishes select original research reports and articles describing cutting-edge techniques and technology in the field.
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