基于机器学习的预测近视及其进展的算法。

Prediction of refractive error and its progression: a machine learning-based algorithm.

机构信息

Technology and Innovation, Carl Zeiss Vision GmbH, Aalen, Germany

Technology and Innovation, Carl Zeiss Vision International GmbH, Aalen, Germany.

出版信息

BMJ Open Ophthalmol. 2023 Oct;8(1). doi: 10.1136/bmjophth-2023-001298.

DOI:10.1136/bmjophth-2023-001298

PMID:37793703

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10551949/

Abstract

OBJECTIVE

Myopia is the refractive error that shows the highest prevalence for younger ages in Southeast Asia and its projection over the next decades indicates that this situation will worsen. Nowadays, several management solutions are being applied to help fight its onset and development, nonetheless, the applications of these techniques depend on a clear and reliable assessment of risk to develop myopia.

METHODS AND ANALYSIS

In this study, population-based data of Chinese children were used to develop a machine learning-based algorithm that enables the risk assessment of myopia's onset and development. Cross-sectional data of 12 780 kids together with longitudinal data of 226 kids containing age, gender, biometry and refractive parameters were used for the development of the models.

RESULTS

A combination of support vector regression and Gaussian process regression resulted in the best performing algorithm. The Pearson correlation coefficient between prediction and measured data was 0.77, whereas the bias was -0.05 D and the limits of agreement was 0.85 D (95% CI: -0.91 to 0.80D).

DISCUSSION

The developed algorithm uses accessible inputs to provide an estimate of refractive development and may serve as guide for the eye care professional to help determine the individual best strategy for management of myopia.

摘要

目的

近视是东南亚年轻人中患病率最高的屈光不正，未来几十年的预测表明这种情况将恶化。如今，有几种管理解决方案正在被应用于帮助对抗近视的发生和发展，但这些技术的应用取决于对近视发生风险的明确和可靠评估。

方法和分析

本研究使用基于人群的中国儿童数据开发了一种基于机器学习的算法，该算法能够评估近视发生和发展的风险。该模型的开发使用了 12780 名儿童的横断面数据和 226 名儿童的纵向数据，其中包含年龄、性别、生物测量和屈光参数。

结果

支持向量回归和高斯过程回归的组合产生了性能最佳的算法。预测数据与实测数据之间的 Pearson 相关系数为 0.77，偏差为-0.05D，一致性界限为 0.85D（95%置信区间：-0.91 至 0.80D）。

讨论

开发的算法使用可获得的输入来提供对屈光发育的估计，可作为眼科医生的指导，帮助确定治疗近视的个体化最佳策略。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/9bb1/10551949/4fdd93bd79c8/bmjophth-2023-001298f01.jpg

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Reference curves for refraction in a German cohort of healthy children and adolescents.

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基于机器学习的预测近视及其进展的算法。

Prediction of refractive error and its progression: a machine learning-based algorithm.

机构信息

出版信息

OBJECTIVE

METHODS AND ANALYSIS

RESULTS

DISCUSSION

目的

方法和分析

结果

讨论

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