Artificial intelligence-based refractive error prediction and EVO-implantable collamer lens power calculation for myopia correction.

IF 5.4 3区材料科学 Q2 CHEMISTRY, PHYSICAL ACS Applied Energy Materials Pub Date : 2023-05-01 DOI:10.1186/s40662-023-00338-1

Yinjie Jiang, Yang Shen, Xun Chen, Lingling Niu, Boliang Li, Mingrui Cheng, Yadi Lei, Yilin Xu, Chongyang Wang, Xingtao Zhou, Xiaoying Wang

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Abstract

Background: Implantable collamer lens (ICL) has been widely accepted for its excellent visual outcomes for myopia correction. It is a new challenge in phakic IOL power calculation, especially for those with low and moderate myopia. This study aimed to establish a novel stacking machine learning (ML) model for predicting postoperative refraction errors and calculating EVO-ICL lens power.

Methods: We enrolled 2767 eyes of 1678 patients (age: 27.5 ± 6.33 years, 18-54 years) who underwent non-toric (NT)-ICL or toric-ICL (TICL) implantation during 2014 to 2021. The postoperative spherical equivalent (SE) and sphere were predicted using stacking ML models [support vector regression (SVR), LASSO, random forest, and XGBoost] and training based on ocular dimensional parameters from NT-ICL and TICL cases, respectively. The accuracy of the stacking ML models was compared with that of the modified vergence formula (MVF) based on the mean absolute error (MAE), median absolute error (MedAE), and percentages of eyes within ± 0.25, ± 0.50, and ± 0.75 diopters (D) and Bland-Altman analyses. In addition, the recommended spheric lens power was calculated with 0.25 D intervals and targeting emmetropia.

Results: After NT-ICL implantation, the random forest model demonstrated the lowest MAE (0.339 D) for predicting SE. Contrarily, the SVR model showed the lowest MAE (0.386 D) for predicting the sphere. After TICL implantation, the XGBoost model showed the lowest MAE for predicting both SE (0.325 D) and sphere (0.308 D). Compared with MVF, ML models had numerically lower values of standard deviation, MAE, and MedAE and comparable percentages of eyes within ± 0.25 D, ± 0.50 D, and ± 0.75 D prediction errors. The difference between MVF and ML models was larger in eyes with low-to-moderate myopia (preoperative SE > - 6.00 D). Our final optimal stacking ML models showed strong agreement between the predictive values of MVF by Bland-Altman plots.

Conclusion: With various ocular dimensional parameters, ML models demonstrate comparable accuracy than existing MVF models and potential advantages in low-to-moderate myopia, and thus provide a novel nomogram for postoperative refractive error prediction and lens power calculation.

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基于人工智能的屈光不正预测及evo -植入式屈光透镜度数计算

背景:人工晶状体(ICL)因其良好的视力效果而被广泛接受。这是人工晶状体度数计算的一个新挑战，特别是对于低、中度近视患者。本研究旨在建立一种新的堆叠机器学习(ML)模型，用于预测术后屈光误差和计算EVO-ICL晶状体度数。方法:2014 - 2021年间，我们招募了1678例接受非环面icl (NT)或环面icl (TICL)植入术的患者2767只眼(年龄:27.5±6.33岁，18-54岁)。分别使用堆叠ML模型[支持向量回归(SVR)、LASSO、随机森林和XGBoost]和基于NT-ICL和TICL病例眼维参数的训练预测术后球形当量(SE)和球体。基于平均绝对误差(MAE)、中位数绝对误差(MedAE)、眼睛在±0.25、±0.50和±0.75屈光度范围内的百分比(D)和Bland-Altman分析，比较叠加ML模型与改进的收敛公式(MVF)的准确性。此外，以0.25 D为间隔，以远视为目标，计算了球透镜的推荐功率。结果:NT-ICL植入后，随机森林模型预测SE的MAE最低(0.339 D)。相反，SVR模型预测球的MAE最低，为0.386 D。植入TICL后，XGBoost模型预测SE (0.325 D)和sphere (0.308 D)的MAE最低，与MVF模型相比，ML模型的标准差、MAE和MedAE数值较低，预测误差在±0.25 D、±0.50 D和±0.75 D范围内的眼睛百分比也较低。在低中度近视(术前SE > - 6.00 D)中，MVF和ML模型的差异更大。我们最终的最优叠加ML模型显示Bland-Altman图的MVF预测值之间具有很强的一致性。结论:ML模型与现有MVF模型相比，具有不同的眼尺寸参数，具有相当的准确性，在低中度近视中具有潜在的优势，为术后屈光不正预测和晶状体度数计算提供了一种新的模态图。

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来源期刊

ACS Applied Energy Materials Materials Science-Materials Chemistry

CiteScore

10.30

自引率

6.20%

发文量

1368

期刊介绍： ACS Applied Energy Materials is an interdisciplinary journal publishing original research covering all aspects of materials, engineering, chemistry, physics and biology relevant to energy conversion and storage. The journal is devoted to reports of new and original experimental and theoretical research of an applied nature that integrate knowledge in the areas of materials, engineering, physics, bioscience, and chemistry into important energy applications.