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KMID : 0213520230370020095
Korean Journal of Ophthalmology
2023 Volume.37 No. 2 p.95 ~ p.104
Deep Learning-based Prediction of Axial Length Using Ultra-widefield Fundus Photography
Oh Ri-Chul

Lee Eun-Kyoung
Bae Kun-Ho
Park Un-Chul
Yu Hyeong-Gon
Yoon Chang-Ki
Abstract
Purpose: To develop a deep learning model that can predict the axial lengths of eyes using ultra-widefield (UWF) fundus photography.

Methods: We retrospectively enrolled patients who visited the ophthalmology clinic at the Seoul National University Hospitalbetween September 2018 and December 2021. Patients with axial length measurements and UWF images taken within 3months of axial length measurement were included in the study. The dataset was divided into a development set and a testset at an 8:2 ratio while maintaining an equal distribution of axial lengths (stratified splitting with binning). We used transferlearning-based on EfficientNet B3 to develop the model. We evaluated the model¡¯s performance using mean absolute error(MAE), R-squared (R2), and 95% confidence intervals (CIs). We used vanilla gradient saliency maps to illustrate the regions predominantlyused by convolutional neural network.

Results: In total, 8,657 UWF retinal fundus images from 3,829 patients (mean age, 63.98 ¡¾15.25 years) were included in thestudy. The deep learning model predicted the axial lengths of the test dataset with MAE and R2 values of 0.744 mm (95% CI,0.709?0.779 mm) and 0.815 (95% CI, 0.785?0.840), respectively. The model¡¯s accuracy was 73.7%, 95.9%, and 99.2% in prediction,with error margins of ¡¾1.0, ¡¾2.0, and ¡¾3.0 mm, respectively.

Conclusions: We developed a deep learning-based model for predicting the axial length from UWF images with good performance.
KEYWORD
Biometry, Deep learning' Myopia, Retina
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