Next-Generation Tear Meniscus Height Detecting and Measuring Smartphone-Based Deep Learning Algorithm Leads in Dry Eye Management

IF 3.2 Q1 OPHTHALMOLOGY Ophthalmology science Pub Date : 2024-05-06 DOI:10.1016/j.xops.2024.100546

Farhad Nejat PhD , Shima Eghtedari MSc , Fatemeh Alimoradi MSc

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Abstract

Purpose

This study aims to develop and assess an infrastructure using Python-based deep learning code for future diagnostic and management purposes related to dry eye disease (DED) utilizing smartphone images.

Design

Cross-sectional study using data which was gathered in Vision Health Research Clinic.

Participants

One thousand twenty-one eye images from 734 patients were included in this article that categorizes into 70% females and 30% males, with no sex and age limit.

Methods

One specialist captured eye images using Samsung A71 (601 images) and iPhone 11 (420 images) cell phones with the flashlight on and direct gaze to the camera. These images include the area of only 1 eye (left/right).

Main Outcome Measures

First, our specialist did 3 different segmentations for every eye image separately for 80% of the training data. This part contains eye, lower eyelid, and iris segmentation. In 20% of test data after automated cropping of the lower eyelid margin and upscaling by 8×, the appropriate tear meniscus height segmentation will be chosen and measured using a deep learning algorithm.

Results

The model was trained on 80% of the data and 20% of the data used for validation from both phones with different resolutions. The dice coefficient of the trained model for validation data is 98.68%, and the accuracy of the overall model is 95.39%.

Conclusions

It appears that this algorithm holds the potential to herald an evolution in the future of diagnosis and management of DED by homecare devices solely through smartphones.

Financial Disclosure(s)

The author(s) have no proprietary or commercial interest in any materials discussed in this article.

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基于智能手机深度学习算法的下一代泪液半月板高度检测和测量技术引领干眼症治疗

目的本研究旨在开发和评估一种基于 Python 深度学习代码的基础架构，用于未来利用智能手机图像对干眼症（DED）进行诊断和管理。方法一位专家使用三星 A71（601 张图片）和 iPhone 11（420 张图片）手机，打开手电筒并直接注视摄像头，捕捉眼睛图像。这些图像只包括一只眼睛（左眼/右眼）的区域。主要结果测量首先，我们的专家对80%的训练数据中的每张眼睛图像分别进行了3次不同的分割。这部分包括眼球、下眼睑和虹膜分割。在自动裁剪下眼睑边缘并放大 8 倍后，在 20% 的测试数据中，将选择适当的泪液半月板高度分割，并使用深度学习算法进行测量。验证数据训练模型的骰子系数为 98.68%，整体模型的准确率为 95.39%。结论看来，该算法有可能预示着未来仅通过智能手机的家庭护理设备诊断和管理 DED 的发展。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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