基于纹理分析特征训练的几种分类器的机器学习研究，以区分 T1-MRI 图像中的良性和恶性软组织肿瘤。

Machine learning study of several classifiers trained with texture analysis features to differentiate benign from malignant soft-tissue tumors in T1-MRI images.

机构信息

Vision Laboratory (VisieLab), Department of Physics, University of Antwerp, Belgium.

出版信息

J Magn Reson Imaging. 2010 Mar;31(3):680-9. doi: 10.1002/jmri.22095.

DOI:10.1002/jmri.22095

PMID:20187212

Abstract

PURPOSE

To study, from a machine learning perspective, the performance of several machine learning classifiers that use texture analysis features extracted from soft-tissue tumors in nonenhanced T1-MRI images to discriminate between malignant and benign tumors.

MATERIALS AND METHODS

Texture analysis features were extracted from the tumor regions from T1-MRI images of clinically proven cases of 49 malignant and 86 benign soft-tissue tumors. Three conventional machine learning classifiers were trained and tested. The best classifier was compared to the radiologists by means of the McNemar's statistical test.

RESULTS

The SVM classifier performs better than the neural network and the C4.5 decision tree based on the analysis of their receiver operating curves (ROC) and cost curves. The classification accuracy of the SVM, which was 93% (91% specificity; 94% sensitivity), was better than the radiologist classification accuracy of 90% (92% specificity; 81% sensitivity).

CONCLUSION

Machine learning classifiers trained with texture analysis features are potentially valuable for detecting malignant tumors in T1-MRI images. Analysis of the learning curves of the classifiers showed that a training data size smaller than 100 T1-MRI images is sufficient to train a machine learning classifier that performs as well as expert radiologists.

摘要

目的

从机器学习的角度研究，使用从软组织肿瘤的未增强 T1-MRI 图像中提取的纹理分析特征的几种机器学习分类器的性能，以区分良恶性肿瘤。

材料与方法

从经临床证实的 49 例恶性和 86 例良性软组织肿瘤的 T1-MRI 图像的肿瘤区域中提取纹理分析特征。训练和测试了三种传统的机器学习分类器。通过麦克内马尔统计检验将最佳分类器与放射科医生进行比较。

结果

支持向量机（SVM）分类器的表现优于神经网络和 C4.5 决策树，这是基于其接收者操作曲线（ROC）和成本曲线的分析。SVM 的分类准确率为 93%（特异性为 91%；敏感性为 94%），优于放射科医生的 90%（特异性为 92%；敏感性为 81%）。

结论

使用纹理分析特征训练的机器学习分类器对于在 T1-MRI 图像中检测恶性肿瘤具有潜在价值。分类器的学习曲线分析表明，训练数据大小小于 100 个 T1-MRI 图像足以训练与专家放射科医生表现相当的机器学习分类器。

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基于纹理分析特征训练的几种分类器的机器学习研究，以区分 T1-MRI 图像中的良性和恶性软组织肿瘤。

Machine learning study of several classifiers trained with texture analysis features to differentiate benign from malignant soft-tissue tumors in T1-MRI images.

机构信息

出版信息

PURPOSE

MATERIALS AND METHODS

RESULTS

CONCLUSION

目的

材料与方法

结果

结论

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