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长短有别:从眼科学和人口统计学变量评估近视眼中的眼轴长度估计。

The long and short of it: a comprehensive assessment of axial length estimation in myopic eyes from ocular and demographic variables.

机构信息

Centre for Eye Research Ireland, Environmental Sustainability & Health Institute, Technological University Dublin, Dublin, Ireland.

Ocumetra Ltd., Dublin, Ireland.

出版信息

Eye (Lond). 2024 May;38(7):1333-1341. doi: 10.1038/s41433-023-02899-w. Epub 2024 Jan 10.

DOI:10.1038/s41433-023-02899-w
PMID:38200321
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11076636/
Abstract

BACKGROUND/OBJECTIVES: Axial length, a key measurement in myopia management, is not accessible in many settings. We aimed to develop and assess machine learning models to estimate the axial length of young myopic eyes.

SUBJECTS/METHODS: Linear regression, symbolic regression, gradient boosting and multilayer perceptron models were developed using age, sex, cycloplegic spherical equivalent refraction (SER) and corneal curvature. Training data were from 8135 (28% myopic) children and adolescents from Ireland, Northern Ireland and China. Model performance was tested on an additional 300 myopic individuals using traditional metrics alongside the estimated axial length vs age relationship. Linear regression and receiver operator characteristics (ROC) curves were used for statistical analysis. The contribution of the effective crystalline lens power to error in axial length estimation was calculated to define the latter's physiological limits.

RESULTS

Axial length estimation models were applicable across all testing regions (p ≥ 0.96 for training by testing region interaction). The linear regression model performed best based on agreement metrics (mean absolute error [MAE] = 0.31 mm, coefficient of repeatability = 0.79 mm) and a smooth, monotonic estimated axial length vs age relationship. This model was better at identifying high-risk eyes (axial length >98th centile) than SER alone (area under the curve 0.89 vs 0.79, respectively). Without knowing lens power, the calculated limits of axial length estimation were 0.30 mm for MAE and 0.75 mm for coefficient of repeatability.

CONCLUSIONS

In myopic eyes, we demonstrated superior axial length estimation with a linear regression model utilising age, sex and refractive metrics and showed its clinical utility as a risk stratification tool.

摘要

背景/目的:眼轴长度是近视管理的关键测量指标,但在许多情况下无法获得。我们旨在开发和评估机器学习模型,以估计年轻近视眼的眼轴长度。

受试者/方法:使用年龄、性别、睫状肌麻痹球镜等效屈光度(SER)和角膜曲率开发了线性回归、符号回归、梯度提升和多层感知器模型。训练数据来自爱尔兰、北爱尔兰和中国的 8135 名(28%为近视)儿童和青少年。使用传统指标以及估计的眼轴长度与年龄关系,在另外 300 名近视个体上测试模型性能。线性回归和接收者操作特征(ROC)曲线用于统计分析。计算有效晶状体屈光力对眼轴长度估计误差的贡献,以确定后者的生理极限。

结果

眼轴长度估计模型适用于所有测试区域(训练与测试区域交互作用的 p 值≥0.96)。基于一致性指标,线性回归模型表现最佳(平均绝对误差 [MAE] = 0.31 毫米,可重复性系数 = 0.79 毫米),并且具有平滑、单调的估计眼轴长度与年龄关系。与单独的 SER 相比,该模型更能识别高风险眼(眼轴长度>第 98 百分位数)(曲线下面积分别为 0.89 和 0.79)。在不知道晶状体屈光力的情况下,眼轴长度估计的计算极限为 MAE 为 0.30 毫米,可重复性系数为 0.75 毫米。

结论

在近视眼中,我们使用年龄、性别和屈光指标的线性回归模型实现了优越的眼轴长度估计,并展示了其作为风险分层工具的临床实用性。