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一种用于眼底图像血管分割的判别式训练全连接条件随机场模型

A Discriminatively Trained Fully Connected Conditional Random Field Model for Blood Vessel Segmentation in Fundus Images.

作者信息

Orlando Jose Ignacio, Prokofyeva Elena, Blaschko Matthew B

出版信息

IEEE Trans Biomed Eng. 2017 Jan;64(1):16-27. doi: 10.1109/TBME.2016.2535311. Epub 2016 Feb 26.

DOI:10.1109/TBME.2016.2535311
PMID:26930672
Abstract

GOAL

In this work, we present an extensive description and evaluation of our method for blood vessel segmentation in fundus images based on a discriminatively trained fully connected conditional random field model.

METHODS

Standard segmentation priors such as a Potts model or total variation usually fail when dealing with thin and elongated structures. We overcome this difficulty by using a conditional random field model with more expressive potentials, taking advantage of recent results enabling inference of fully connected models almost in real time. Parameters of the method are learned automatically using a structured output support vector machine, a supervised technique widely used for structured prediction in a number of machine learning applications.

RESULTS

Our method, trained with state of the art features, is evaluated both quantitatively and qualitatively on four publicly available datasets: DRIVE, STARE, CHASEDB1, and HRF. Additionally, a quantitative comparison with respect to other strategies is included.

CONCLUSION

The experimental results show that this approach outperforms other techniques when evaluated in terms of sensitivity, F1-score, G-mean, and Matthews correlation coefficient. Additionally, it was observed that the fully connected model is able to better distinguish the desired structures than the local neighborhood-based approach.

SIGNIFICANCE

Results suggest that this method is suitable for the task of segmenting elongated structures, a feature that can be exploited to contribute with other medical and biological applications.

摘要

目标

在这项工作中,我们对基于判别式训练的全连接条件随机场模型的眼底图像血管分割方法进行了全面描述和评估。

方法

标准的分割先验,如Potts模型或总变分,在处理细而长的结构时通常会失效。我们通过使用具有更强表达能力势函数的条件随机场模型克服了这一困难,利用了最近能够几乎实时推断全连接模型的成果。该方法的参数使用结构化输出支持向量机自动学习,这是一种在许多机器学习应用中广泛用于结构化预测的监督技术。

结果

我们的方法使用最先进的特征进行训练,在四个公开可用的数据集:DRIVE、STARE、CHASEDB1和HRF上进行了定量和定性评估。此外,还包括与其他策略的定量比较。

结论

实验结果表明,在灵敏度、F1分数、G均值和马修斯相关系数方面进行评估时,该方法优于其他技术。此外,观察到全连接模型比基于局部邻域的方法能够更好地区分所需结构。

意义

结果表明,该方法适用于分割细长结构的任务,这一特性可用于其他医学和生物学应用。

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