Encoded Texture Features to Characterize Bone Radiograph Images

Osteoporosis is the most common reason that causes the fracture among the elderly. For the purpose of convenience and safety, 2D texture analysis has been used to diagnose osteoporosis. In this study, a supervised method using proposed texture features to identify osteoporotic cases from healthy was proposed. We designed two groups of new features, Encoded GLCM and Encoded LBP, each of which contains two subgroups through encoding the Gabor and Hessian information into the Gray Level Co-Occurrence Matrix (GLCM) features and Local Binary Patterns (LBP) features respectively. These two groups of features, together with the raw feature group containing the GLCM and LBP features, totally 560 features, were categorized into various groups and used to train the Random Forest classifier. Classification performances using these features were compared inter-and intra-groups/subgroups. And the performance using each individual feature was also provided. We conducted feature selection based on Recursive Feature Elimination (RFE) inside a voting scheme to further increase the efficiency. The inter-and intra-groups/subgroups results indicate that the Encoded GLCM and Encoded LBP, are more discriminative than the raw GLCM and LBP features for the identification of the osteoporosis; The best individual feature is from the Encoded LBP group and can achieve 70% of balanced accuracy; Furthermore, using only ten of the proposed features through feature selection, the balanced accuracy can even be improved from 60% to 71%. This shows that the proposed method is promising to assist the early diagnosis of osteoporosis.

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