Introduction: Ocular surface squamous neoplasia (OSSN) is a broad entity encompassing a spectrum of squamous neoplasms of conjunctiva and cornea. This study aimed to explore the utility of artificial intelligence (AI) models in detecting OSSN from slit-lamp (SL) images. Methods: This is a retrospective observational study. SL images of OSSN disease, non-OSSN ocular surface lesions (OOSD), and normal ocular surfaces (N) were collected (2013–2023). Images with minimum resolution of 1,024 × 1,024 pixels under diffuse illumination were included. Data were divided into training and testing sets (85:15). Deep learning (DL) algorithms were applied for ternary classification of the SL images (OSSN, OOSD, and normal). Three AI models – MobileNetV2, Xception, and DenseNet121 – were used in the study. A fivefold cross-validation strategy was utilized for robust model evaluation. Results: A total of 163 images in OSSN group, 202 in OOSD group, and 269 normal ocular surface images were included (n = 634). Data augmentation was performed to increase and balance the data. The average accuracies for OSSN detection for DenseNet121, MobileNetV2, and Xception were 83%, 88.8%, and 84.5%, respectively. MobileNetV2 and Xception had a similar average sensitivity for OSSN detection (74%) while MobileNetV2 was the most specific DL algorithm (96.25%) for OSSN detection. Conclusions: AI models showed good performance in image-based OSSN detection. AI models may provide a promising tool for OSSN screening in primary health care centers and for teleconsultation from remote areas in the future.

Journal Section:
Clinical Research
Keywords:
Artificial intelligence, Deep learning, Ocular surface squamous neoplasia, Slit-lamp image
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