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用于自动测量视网膜小动脉直径的计算机算法。

Computer algorithms for the automated measurement of retinal arteriolar diameters.

作者信息

Chapman N, Witt N, Gao X, Bharath A A, Stanton A V, Thom S A, Hughes A D

机构信息

Department of Clinical Pharmacology, School of Medicine at NHLI, Imperial College of Science, Technology and Medicine, St Mary's Hospital, London W2 1NY, UK.

出版信息

Br J Ophthalmol. 2001 Jan;85(1):74-9. doi: 10.1136/bjo.85.1.74.

DOI:10.1136/bjo.85.1.74
PMID:11133716
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1723694/
Abstract

AIMS

Quantification of retinal vascular change is difficult and manual measurements of vascular features are slow and subject to observer bias. These problems may be overcome using computer algorithms. Three automated methods and a manual method for measurement of arteriolar diameters from digitised red-free retinal photographs were compared.

METHODS

60 diameters (in pixels) measured by manual identification of vessel edges in red-free retinal images were compared with diameters measured by (1) fitting vessel intensity profiles to a double Gaussian function by non-linear regression, (2) a standard edge detection algorithm (Sobel), and (3) determination of points of maximum intensity variation by a sliding linear regression filter (SLRF). Method agreement was analysed using Bland-Altman plots and the repeatability of each method was assessed.

RESULTS

Diameter estimations obtained using the SLRF method were the least scattered although diameters obtained were approximately 3 pixels greater than those measured manually. The SLRF method was the most repeatable and the Gaussian method less so. The Sobel method was the least consistent owing to frequent misinterpretation of the light reflex as the vessel edge.

CONCLUSION

Of the three automated methods compared, the SLRF method was the most consistent (defined as the method producing diameter estimations with the least scatter) and the most repeatable in measurements of retinal arteriolar diameter. Application of automated methods of retinal vascular analysis may be useful in the assessment of cardiovascular and other diseases.

摘要

目的

视网膜血管变化的量化较为困难,血管特征的手动测量速度慢且易受观察者偏差影响。使用计算机算法或许可以克服这些问题。比较了三种自动测量方法和一种手动测量方法,用于从数字化无赤光视网膜照片中测量小动脉直径。

方法

将通过手动识别无赤光视网膜图像中的血管边缘测量得到的60个直径(以像素为单位),与通过以下方法测量的直径进行比较:(1)通过非线性回归将血管强度轮廓拟合为双高斯函数;(2)一种标准边缘检测算法(Sobel);(3)通过滑动线性回归滤波器(SLRF)确定最大强度变化点。使用Bland-Altman图分析方法的一致性,并评估每种方法的可重复性。

结果

使用SLRF方法获得的直径估计值离散度最小,不过所获得的直径比手动测量的大约大3个像素。SLRF方法的可重复性最高,高斯方法的可重复性稍低。Sobel方法最不一致,因为经常将光反射误判为血管边缘。

结论

在比较的三种自动测量方法中,SLRF方法在测量视网膜小动脉直径时最一致(定义为产生直径估计值离散度最小的方法)且可重复性最高。视网膜血管分析自动方法的应用可能有助于评估心血管疾病和其他疾病。

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