A classification approach to prostate cancer localization in 3T multi-parametric MRI

A classification approach to prostate cancer localization in 3T multi-parametric MRI

Multiparametric-magnetic resonance imaging (mp-MRI) has demonstrated, in many studies, its potential in prostate cancer detection and analysis. We propose a supervised classification approach based on mp-MRI data base of 20 patients, in order to localize prostate cancer and to achieve a cartographic...

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Bibliographic Details
Published in:2016 2nd International Conference on Advanced Technologies for Signal and Image Processing (ATSIP) pp. 113 - 118
Main Authors: Trigui, Rania, Miteran, Johel, Sellami, Lamia, Walker, Paul, Ben Hamida, Ahmed
Format: Conference Proceeding
Language:English
Published: IEEE 01-03-2016
Subjects:
Data mining
Error analysis
Feature extraction
Magnetic resonance imaging
mp-MRI
Prostate cancer
Random forest
Support vector machines
SVM
Online Access:Get full text
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Summary:Multiparametric-magnetic resonance imaging (mp-MRI) has demonstrated, in many studies, its potential in prostate cancer detection and analysis. We propose a supervised classification approach based on mp-MRI data base of 20 patients, in order to localize prostate cancer and to achieve a cartographic representation of the prostate voxels based on classification results. Proposed method provides a computer aided detection (CAD) software for prostatic cancer. For that, we have extracted varied features providing functional, anatomical and metabolic information helping the classifier to distinguish between three different classes ("Healthy", "Benign" and "Pathologic"). We started by evaluating Support Vector Machine (SVM) ability to separate healthy and pathologic voxels. We obtained an error rate of 0.99%, specificity 99.25% and sensitivity 98.85%. Then, by introducing "Benign" voxels, SVM gave an error rate of 26% using MRSI, Diffusion-Weighted MRI and Dynamic Contrast-Enhanced MRI. Next, we evaluated Random Forest performances which gave error rate of 24.60% when separating three different classes using MRSI, T2-MRI, Diffusion-Weighted MRI and Dynamic Contrast-Enhanced MRI. Finally, we presented color-coded maps based on classification results.
DOI:10.1109/ATSIP.2016.7523064