Computerized analysis of mammographic microcalcifications in morphological and texture feature spaces

Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/134952/1/mp8389.pd

Mammography

In this volume, the topics are constructed from a variety of contents: the bases of mammography systems, optimization of screening mammography with reference to evidence-based research, new technologies of image acquisition and its surrounding systems, and case reports with reference to up-to-date multimodality images of breast cancer. Mammography has been lagged in the transition to digital imaging systems because of the necessity of high resolution for diagnosis. However, in the past ten years, technical improvement has resolved the difficulties and boosted new diagnostic systems. We hope that the reader will learn the essentials of mammography and will be forward-looking for the new technologies. We want to express our sincere gratitude and appreciation?to all the co-authors who have contributed their work to this volume

Modular Machine Learning Methods for Computer-Aided Diagnosis of Breast Cancer

The purpose of this study was to improve breast cancer diagnosis by reducing the number of benign biopsies performed. To this end, we investigated modular and ensemble systems of machine learning methods for computer-aided diagnosis (CAD) of breast cancer. A modular system partitions the input space into smaller domains, each of which is handled by a local model. An ensemble system uses multiple models for the same cases and combines the models\u27 predictions. Five supervised machine learning techniques (LDA, SVM, BP-ANN, CBR, CART) were trained to predict the biopsy outcome from mammographic findings (BIRADS™) and patient age based on a database of 2258 cases mixed from multiple institutions. The generalization of the models was tested on second set of 2177 cases. Clusters were identified in the database using a priori knowledge and unsupervised learning methods (agglomerative hierarchical clustering followed by K-Means, SOM, AutoClass). The performance of the global models over the clusters was examined and local models were trained for clusters. While some local models were superior to some global models, we were unable to build a modular CAD system that was better than the global BP-ANN model. The ensemble systems based on simplistic combination schemes did not result in significant improvements and more complicated combination schemes were found to be unduly optimistic. One of the most striking results of this dissertation was that CAD systems trained on a mixture of lesion types performed much better on masses than on calcifications. Our study of the institutional effects suggests that models built on cases mixed between institutions may overcome some of the weaknesses of models built on cases from a single institution. It was suggestive that each of the unsupervised methods identified a cluster of younger women with well-circumscribed or obscured, oval-shaped masses that accounted for the majority of the BP-ANN’s recommendations for follow up. From the cluster analysis and the CART models, we determined a simple diagnostic rule that performed comparably to the global BP-ANN. Approximately 98% sensitivity could be maintained while providing approximately 26% specificity. This should be compared to the clinical status quo of 100% sensitivity and 0% specificity on this database of indeterminate cases already referred to biopsy

Computer-aided classification of mammographic masses and normal tissue: linear discriminant analysis in texture feature space

The authors studied the effectiveness of using texture features derived from spatial grey level dependence (SGLD) matrices for classification of masses and normal breast tissue on mammograms. One hundred and sixty-eight regions of interest (ROIS) containing biopsy-proven masses and 504 ROIS containing normal breast tissue were extracted from digitized mammograms for this study. Eight features were calculated for each ROI. The importance of each feature in distinguishing masses from normal tissue was determined by stepwise linear discriminant analysis. Receiver operating characteristic (ROC) methodology was used to evaluate the classification accuracy. The authors investigated the dependence of classification accuracy on the input features, and on the pixel distance and bit depth in the construction of the SGLD matrices. It was found that five of the texture features were important for the classification. The dependence of classification accuracy on distance and bit depth was weak for distances greater than 12 pixels and bit depths greater than seven bits. By randomly and equally dividing the data set into two groups, the classifier was trained and tested on independent data sets. The classifier achieved an average area under the ROC curve, Az, of 0.84 during training and 0.82 during testing. The results demonstrate the feasibility of using linear discriminant analysis in the texture feature space for classification of true and false detections of masses on mammograms in a computer-aided diagnosis scheme.Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/48960/2/pb950510.pd

Optimization of Network Topology in Computer-Aided Detection Schemes Using Phased Searching with NEAT in a Time-Scaled Framework

In the field of computer-aided mammographic mass detection, many different features and classifiers have been tested. Frequently, the relevant features and optimal topology for the artificial neural network (ANN)-based approaches at the classification stage are unknown, and thus determined by trial-and-error experiments. In this study, we analyzed a classifier that evolves ANNs using genetic algorithms (GAs), which combines feature selection with the learning task. The classifier named “Phased Searching with NEAT in a Time-Scaled Framework” was analyzed using a dataset with 800 malig-nant and 800 normal tissue regions in a 10-fold cross-validation framework. The classification performance measured by the area under a receiver operating characteristic (ROC) curve was 0.856 ± 0.029. The result was also compared with four other well-established classifiers that include fixed-topology ANNs, support vector machines (SVMs), linear discriminant analysis (LDA), and bagged decision trees. The results show that Phased Searching outperformed the LDA and bagged decision tree classifiers, and was only significantly outperformed by SVM. Furthermore, the Phased Searching method required fewer features and discarded superfluous structure or topology, thus incurring a lower feature computational and training and validation time requirement. Analyses performed on the network complexities evolved by Phased Searching indicate that it can evolve optimal network topologies based on its complexi-fication and simplification parameter selection process. From the results, the study also concluded that the three classifiers – SVM, fixed-topology ANN, and Phased Searching with NeuroEvolution of Augmenting Topologies (NEAT) in a Time-Scaled Framework – are performing comparably well in our mammographic mass detection scheme.Ye

Developing Novel Computer Aided Diagnosis Schemes for Improved Classification of Mammography Detected Masses

Mammography imaging is a population-based breast cancer screening tool that has greatly aided in the decrease in breast cancer mortality over time. Although mammography is the most frequently employed breast imaging modality, its performance is often unsatisfactory with low sensitivity and high false positive rates. This is due to the fact that reading and interpreting mammography images remains difficult due to the heterogeneity of breast tumors and dense overlapping fibroglandular tissue. To help overcome these clinical challenges, researchers have made great efforts to develop computer-aided detection and/or diagnosis (CAD) schemes to provide radiologists with decision-making support tools. In this dissertation, I investigate several novel methods for improving the performance of a CAD system in distinguishing between malignant and benign masses. The first study, we test the hypothesis that handcrafted radiomics features and deep learning features contain complementary information, therefore the fusion of these two types of features will increase the feature representation of each mass and improve the performance of CAD system in distinguishing malignant and benign masses. Regions of interest (ROI) surrounding suspicious masses are extracted and two types of features are computed. The first set consists of 40 radiomic features and the second set includes deep learning (DL) features computed from a pretrained VGG16 network. DL features are extracted from two pseudo color image sets, producing a total of three feature vectors after feature extraction, namely: handcrafted, DL-stacked, DL-pseudo. Linear support vector machines (SVM) are trained using each feature set alone and in combinations. Results show that the fusion CAD system significantly outperforms the systems using either feature type alone (AUC=0.756±0.042 p<0.05). This study demonstrates that both handcrafted and DL futures contain useful complementary information and that fusion of these two types of features increases the CAD classification performance. In the second study, we expand upon our first study and develop a novel CAD framework that fuses information extracted from ipsilateral views of bilateral mammograms using both DL and radiomics feature extraction methods. Each case in this study is represented by four images which includes the craniocaudal (CC) and mediolateral oblique (MLO) view of left and right breast. First, we extract matching ROIs from each of the four views using an ipsilateral matching and bilateral registration scheme to ensure masses are appropriately matched. Next, the handcrafted radiomics features and VGG16 model-generated features are extracted from each ROI resulting in eight feature vectors. Then, after reducing feature dimensionality and quantifying the bilateral asymmetry, we test four fusion methods. Results show that multi-view CAD systems significantly outperform single-view systems (AUC = 0.876±0.031 vs AUC = 0.817±0.026 for CC view and 0.792±0.026 for MLO view, p<0.001). The study demonstrates that the shift from single-view CAD to four-view CAD and the inclusion of both deep transfer learning and radiomics features increases the feature representation of the mass thus improves CAD performance in distinguishing between malignant and benign breast lesions. In the third study, we build upon the first and second studies and investigate the effects of pseudo color image generation in classifying suspicious mammography detected breast lesions as malignant or benign using deep transfer learning in a multi-view CAD scheme. Seven pseudo color image sets are created through a combination of the original grayscale image, a histogram equalized image, a bilaterally filtered image, and a segmented mass image. Using the multi-view CAD framework developed in the previous study, we observe that the two pseudo-color sets created using a segmented mass in one of the three image channels performed significantly better than all other pseudo-color sets (AUC=0.882, p<0.05 for all comparisons and AUC=0.889, p<0.05 for all comparisons). The results of this study support our hypothesis that pseudo color images generated with a segmented mass optimize the mammogram image feature representation by providing increased complementary information to the CADx scheme which results in an increase in the performance in classifying suspicious mammography detected breast lesions as malignant or benign. In summary, each of the studies presented in this dissertation aim to increase the accuracy of a CAD system in classifying suspicious mammography detected masses. Each of these studies takes a novel approach to increase the feature representation of the mass that needs to be classified. The results of each study demonstrate the potential utility of these CAD schemes as an aid to radiologists in the clinical workflow

Precision Imaging Ultrasound Technology - Does It Improve Accuracy And Increase Confidence In Diagnosing Breast Tumours?

Objective To determine the effect of Precision Imaging (PI), an innovative speckle reduction algorithm, on the diagnostic efficacy in breast ultrasound Material and methods Patients aged from 20 to 84 years screened by the breast clinic from October 2010 to June 2011 were included in this research. The commercial ultrasound scanner Toshiba AplioMX, with compact linear transducers 15-7MHz and 12-5 MHz was used for image acquisition. A single projection image that was considered to best represent the lesion was recorded without PI (L0), then with all other 3 levels of PI, namely Precision 1 (L1), Precision 2 (L2) and Precision 3 (L3), with higher numbers signifying greater speckle reduction. Fifty one breast lesions (20 malignant and 31 benign) were selected from over 200 collected lesions, with selection criteria based on the 1- 5 classification system developed by National Breast Cancer Centre in collaboration with the Royal Australian and New Zealand College of Radiologists. These selected images were cropped to remove the technical details, which included patient information as well as PI level. These processed images were then organised into four sets (A,B,C,D) with images in same PI level. These four sets of images were evaluated by six radiologists and six sonographers dedicated to breast imaging, scoring each lesion between 1 and 6.These scores were subjected to Q-Perform software, DBMMRMC, Mann-Whitney U-test, Wilcoxon Signed rank test and IBM SPSS statistics for statistical analyses. Results The overall means ROCAUC for L0 was 0.79, L1 was 0.80, L2 was 0.81, and L3 was 0.81. The overall means sensitivity for L0 was 0.75, L1 was 0.79, L2 was 0.80, and L3 was 0.78.Overall means specificity for L0 was 0.74, L1 was 0.72, L2 was 0.73, and L3 was 0.71. Conclusion The data analysis on ROC, sensitivity, and specificity did not demonstrate any significant improvement in diagnostic efficacy amongst expert observers in this study