Abstract
Breast Cancer is the most prevalent cancer among women across the globe. Automatic detection of breast cancer using Computer Aided Diagnosis (CAD) system suffers from false positives (FPs). Thus, reduction of FP is one of the challenging tasks to improve the performance of the diagnosis systems. In the present work, new FP reduction technique has been proposed for breast cancer diagnosis. It is based on appropriate integration of preprocessing, Self-organizing map (SOM) clustering, region of interest (ROI) extraction, and FP reduction. In preprocessing, contrast enhancement of mammograms has been achieved using Local Entropy Maximization algorithm. The unsupervised SOM clusters an image into number of segments to identify the cancerous region and extracts tumor regions (i.e., ROIs). However, it also detects some FPs which affects the efficiency of the algorithm. Therefore, to reduce the FPs, the output of the SOM is given to the FP reduction step which is aimed to classify the extracted ROIs into normal and abnormal class. FP reduction consists of feature mining from the ROIs using proposed local sparse curvelet coefficients followed by classification using artificial neural network (ANN). The performance of proposed algorithm has been validated using the local datasets as TMCH (Tata Memorial Cancer Hospital) and publicly available MIAS (Suckling et al., 1994) and DDSM (Heath et al., 2000) database. The proposed technique results in reduction of FPs from 0.85 to 0.02 FP/image for MIAS, 4.81 to 0.16 FP/image for DDSM, and 2.32 to 0.05 FP/image for TMCH reflecting huge improvement in classification of mammograms.
Highlights
Breast cancer is the most common cancer disease among women across worldwide
Mammographic Image Analysis Society (MIAS) Database. e mini-MIAS [17] database consists of 322 mammograms, each having 1024 × 1024 pixels and annotated like background tissue character, class, severity, center of abnormality, and radius of circle for abnormality. is database includes 64 benign, 51 malignant, and 207 normal cases, which have been taken for experimentation
It has been observed during experimentation that the curvelet coe cients on an average are reduced for sparse local binary patterns (LBPs) by 14%, 32%, 33%, and 34% for MIAS, Digital Database for Screening Mammography (DDSM), Tata Memorial Cancer Hospital (TMCH): Scanner1, and TMCH: Scanner2, respectively
Summary
Breast cancer is the most common cancer disease among women across worldwide. It is the leading cause of deaths for women suffering from cancer disease in India. (1) Preprocessing of mammogram image for contrast enhancement using local entropy maximizationbased image fusion algorithm and removal of background noise (2) Cluster-based segmentation of mammograms using SOM and extract tumor regions, i.e., ROI). (3) FP reduction: extraction of sparse curvelet subband coefficients and computation of LBP descriptor to classify true positives and false positives to improve performance of CAD system using MIAS [17], DDSM [19], and Tata Memorial Cancer Hospital (TMCH) datasets. E organization of paper is as follows: Sections 1 and 2 illustrate the introduction and literature review on automatic segmentation and extraction of abnormal masses (i.e., tumor region) as well as FP reduction methods. Preprocessing. e mammogram images are low-dose x-ray images so they have poor contrast and suffer from noises. e preprocessed mammogram image as shown in Figures 2(a)–2(d) represents preprocessing of mammogram, and Figures 2(e)–2(g) represents SOM clustering and ROI extraction
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