离体人晶状体形状的年龄依赖性傅里叶模型。

Age-dependent Fourier model of the shape of the isolated ex vivo human crystalline lens.

作者信息

Urs Raksha, Ho Arthur, Manns Fabrice, Parel Jean-Marie

机构信息

Ophthalmic Biophysics Center, Bascom Palmer Eye Institute, University of Miami Miller School of Medicine, Miami, FL, USA.

出版信息

Vision Res. 2010 Jun 1;50(11):1041-7. doi: 10.1016/j.visres.2010.03.012. Epub 2010 Mar 23.

DOI:10.1016/j.visres.2010.03.012

PMID:20338192

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2872038/

Abstract

PURPOSE

To develop an age-dependent mathematical model of the zero-order shape of the isolated ex vivo human crystalline lens, using one mathematical function, that can be subsequently used to facilitate the development of other models for specific purposes such as optical modeling and analytical and numerical modeling of the lens.

METHODS

Profiles of whole isolated human lenses (n=30) aged 20-69, were measured from shadow-photogrammetric images. The profiles were fit to a 10th-order Fourier series consisting of cosine functions in polar-co-ordinate system that included terms for tilt and decentration. The profiles were corrected using these terms and processed in two ways. In the first, each lens was fit to a 10th-order Fourier series to obtain thickness and diameter, while in the second, all lenses were simultaneously fit to a Fourier series equation that explicitly include linear terms for age to develop an age-dependent mathematical model for the whole lens shape.

RESULTS

Thickness and diameter obtained from Fourier series fits exhibited high correlation with manual measurements made from shadow-photogrammetric images. The root-mean-squared-error of the age-dependent fit was 205 microm. The age-dependent equations provide a reliable lens model for ages 20-60 years.

CONCLUSION

The contour of the whole human crystalline lens can be modeled with a Fourier series. Shape obtained from the age-dependent model described in this paper can be used to facilitate the development of other models for specific purposes such as optical modeling and analytical and numerical modeling of the lens.

摘要

目的

使用一个数学函数建立离体人晶状体零阶形状的年龄依赖性数学模型，该模型随后可用于促进其他特定用途模型的开发，如光学建模以及晶状体的分析和数值建模。

方法

从阴影摄影图像测量了20至69岁的30个离体人晶状体的轮廓。这些轮廓拟合到极坐标系中由余弦函数组成的十阶傅里叶级数，该级数包括倾斜和偏心项。使用这些项对轮廓进行校正并以两种方式进行处理。第一种方式是，将每个晶状体拟合到十阶傅里叶级数以获得厚度和直径，而第二种方式是，将所有晶状体同时拟合到一个明确包含年龄线性项的傅里叶级数方程，以建立整个晶状体形状的年龄依赖性数学模型。

结果

从傅里叶级数拟合得到的厚度和直径与从阴影摄影图像进行的手动测量显示出高度相关性。年龄依赖性拟合的均方根误差为205微米。年龄依赖性方程为20至60岁的人群提供了一个可靠的晶状体模型。

结论

整个人晶状体的轮廓可以用傅里叶级数建模。本文所述的年龄依赖性模型获得的形状可用于促进其他特定用途模型的开发，如光学建模以及晶状体的分析和数值建模。

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