An automatic microcalcification detection system based on a hybrid neural network classifier

A hybrid intelligent system is presented for the identification of microcalcification clusters in digital mammograms. The proposed method is based on a three-step procedure: (a) preprocessing and segmentation, (b) regions of interest (ROI) specification, and (c) feature extraction and classification...

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Bibliographic Details
Published in:Artificial intelligence in medicine 2002-06, Vol.25 (2), p.149-167
Main Authors: Papadopoulos, A., Fotiadis, D.I., Likas, A.
Format: Article
Language:English
Subjects:
Automation
Calcinosis - classification
Calcinosis - diagnostic imaging
Computer-aided detection (CAD)
Computers, Hybrid
Databases as Topic
Diagnosis, Computer-Assisted
False Positive Reactions
Female
Humans
Hybrid neural network
Mammography
Microcalcification detection
Neural Networks (Computer)
Principal Component Analysis
Radiography
ROC Curve
Sensitivity and Specificity
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Summary:A hybrid intelligent system is presented for the identification of microcalcification clusters in digital mammograms. The proposed method is based on a three-step procedure: (a) preprocessing and segmentation, (b) regions of interest (ROI) specification, and (c) feature extraction and classification. The reduction of false positive cases is performed using an intelligent system containing two sub-systems: a rule-based and a neural network sub-system. In the first step of the classification schema 22 features are automatically computed which refer either to individual microcalcifications or to groups of them. Further reduction in the number of features is achieved through principal component analysis (PCA). The proposed methodology is tested using the Nijmegen and the Mammographic Image Analysis Society (MIAS) mammographic databases. Results are presented as the receiver operating characteristic (ROC) performance and are quantified by the area under the ROC curve ( A z ). In particular, the A z value for the Nijmegen dataset is 0.91 and for the MIAS is 0.92. The detection specificity of the two sets is 1.80 and 1.15 false positive clusters per image, at the sensitivity level higher than 0.90, respectively.
ISSN:0933-3657
1873-2860
DOI:10.1016/S0933-3657(02)00013-1