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视盘大小的测量:校正眼放大率方法的等效性。

Measurement of optic disc size: equivalence of methods to correct for ocular magnification.

作者信息

Garway-Heath D F, Rudnicka A R, Lowe T, Foster P J, Fitzke F W, Hitchings R A

机构信息

Glaucoma Unit, Moorfields Eye Hospital, London.

出版信息

Br J Ophthalmol. 1998 Jun;82(6):643-9. doi: 10.1136/bjo.82.6.643.

DOI:10.1136/bjo.82.6.643
PMID:9797665
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1722616/
Abstract

AIMS

To compare methods available to correct the magnification of images that result from the optics of the eye and identify errors, and source of error, of the methods.

METHODS

11 methods were applied to ocular biometry data from three independent cohorts. Each method was compared with the method of Bennett, which uses most biometric data. The difference between each method and Bennett's is the "error" of the method. The relation between the error and axial length, ametropia, and keratometry was explored by linear regression analysis.

RESULTS

Methods using axial length had the lowest mean (+0.5 to +2.6%) and standard deviation (0.6 to 1.2%) of errors. Of methods using keratometry and ametropia only, the lowest mean (-1.4% to +4.4%) and standard deviation (2.9 to 4.3%) of errors was found for a new method described in this paper, and that used by the Heidelberg retina tomograph (HRT). The highest mean error (+2.2 to +7.1%) was found for Littmann's method. Littmann's correction was larger than the HRT's by 3.5 to 3.7%. The mean difference between the new and HRT methods and the "abbreviated axial length" method of Bennett is -1.3 to +2.0%. The error of the "keratometry and ametropia" methods is related to axial length.

CONCLUSIONS

Methods using axial length are most accurate. The abbreviated axial length method of Bennett differs little from more detailed calculations and is appreciably more accurate than methods using keratometry and ametropia alone. If axial length is unknown, the new and the HRT methods give results closest to the abbreviated axial length method.

摘要

目的

比较用于校正因眼睛光学系统导致的图像放大的可用方法,并识别这些方法的误差及误差来源。

方法

将11种方法应用于来自三个独立队列的眼部生物测量数据。每种方法都与使用大多数生物测量数据的贝内特方法进行比较。每种方法与贝内特方法之间的差异即为该方法的“误差”。通过线性回归分析探讨误差与眼轴长度、屈光不正和角膜曲率测量之间的关系。

结果

使用眼轴长度的方法误差均值(+0.5%至+2.6%)和标准差(0.6%至1.2%)最低。在仅使用角膜曲率测量和屈光不正的方法中,本文描述的一种新方法以及海德堡视网膜断层扫描仪(HRT)所使用方法的误差均值(-1.4%至+4.4%)和标准差(2.9%至4.3%)最低。利特曼方法的误差均值最高(+2.2%至+7.1%)。利特曼校正比HRT的校正大3.5%至3.7%。新方法和HRT方法与贝内特的“简化眼轴长度”方法之间的平均差异为-1.3%至+2.0%。“角膜曲率测量和屈光不正”方法的误差与眼轴长度有关。

结论

使用眼轴长度的方法最为准确。贝内特的简化眼轴长度方法与更详细的计算方法差异不大,且明显比仅使用角膜曲率测量和屈光不正的方法更准确。如果眼轴长度未知,新方法和HRT方法得出的结果最接近简化眼轴长度方法。

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