Investigating the use of texture features for analysis of breast lesions on contrast-enhanced cone beam CT

Cone beam computed tomography (CBCT) has found use in mammography for imaging the entire breast with sufficient spatial resolution at a radiation dose within the range of that of conventional mammography. Recently, enhancement of lesion tissue through the use of contrast agents has been proposed for cone beam CT. This study investigates whether the use of such contrast agents improves the ability of texture features to differentiate lesion texture from healthy tissue on CBCT in an automated manner. For this purpose, 9 lesions were annotated by an experienced radiologist on both regular and contrast-enhanced CBCT images using two-dimensional (2D) square ROIs. These lesions were then segmented, and each pixel within the lesion ROI was assigned a label – lesion or non-lesion, based on the segmentation mask. On both sets of CBCT images, four three-dimensional (3D) Minkowski Functionals were used to characterize the local topology at each pixel. The resulting feature vectors were then used in a machine learning task involving support vector regression with a linear kernel (SVRlin) to classify each pixel as belonging to the lesion or non-lesion region of the ROI. Classification performance was assessed using the area under the receiver-operating characteristic (ROC) curve (AUC). Minkowski Functionals derived from contrastenhanced CBCT images were found to exhibit significantly better performance at distinguishing between lesion and non-lesion areas within the ROI when compared to those extracted from CBCT images without contrast enhancement (p < 0.05). Thus, contrast enhancement in CBCT can improve the ability of texture features to distinguish lesions from surrounding healthy tissue.

[1]  Biao Chen,et al.  Cone-beam volume CT breast imaging: feasibility study. , 2002, Medical physics.

[2]  Anke Meyer-Bäse,et al.  Local exponential stability of competitive neural networks with different time scales , 2004, Eng. Appl. Artif. Intell..

[3]  Thomas Villmann,et al.  Exploratory Observation Machine (XOM) with Kullback-Leibler Divergence for Dimensionality Reduction and Visualization , 2010, ESANN.

[4]  H. Ritter,et al.  The Deformable Feature Map — Adaptive Plasticity for Function Approximation , 1998 .

[5]  Klaus Mecke,et al.  Euler characteristic and related measures for random geometric sets , 1991 .

[6]  Helge J. Ritter,et al.  The deformable feature map - a novel neurocomputing algorithm for adaptive plasticity in pattern analysis , 2002, Neurocomputing.

[7]  Thomas Baum,et al.  Improving bone strength prediction in human proximal femur specimens through geometrical characterization of trabecular bone microarchitecture and support vector regression , 2014, J. Electronic Imaging.

[8]  A. Jemal,et al.  Cancer Statistics, 2007 , 2007, CA: a cancer journal for clinicians.

[9]  Axel Wismüller,et al.  The Exploration Machine - A Novel Method for Data Visualization , 2009, WSOM.

[10]  Mahesh B. Nagarajan,et al.  Performance of topological texture features to classify fibrotic interstitial lung disease patterns. , 2011, Medical physics.

[11]  Axel Wismüller,et al.  Classification of small lesions in dynamic breast MRI: eliminating the need for precise lesion segmentation through spatio-temporal analysis of contrast enhancement , 2012, Machine Vision and Applications.

[12]  Ruola Ning,et al.  Cone-beam CT for breast imaging: Radiation dose, breast coverage, and image quality. , 2010, AJR. American journal of roentgenology.

[13]  Axel Wismüller,et al.  A Neural Network Approach to Functional MRI Pattern Analysis — Clustering of Time-Series by Hierarchical Vector Quantization , 1998 .

[14]  Axel Wismüller,et al.  Prediction of Biomechanical Properties of Trabecular Bone in MR Images With Geometric Features and Support Vector Regression , 2011, IEEE Transactions on Biomedical Engineering.

[15]  M.Kleinberg Jon,et al.  Advances in Self-Organizing Maps, 7th International Workshop, WSOM 2009, St. Augustine, FL, USA, June 8-10, 2009. Proceedings , 2009, WSOM.

[16]  Thomas Villmann,et al.  Neighbor embedding XOM for dimension reduction and visualization , 2011, Neurocomputing.

[17]  Axel Wismüller,et al.  Classification of Small Lesions in Breast MRI: Evaluating The Role of Dynamically Extracted Texture Features Through Feature Selection. , 2013, Journal of medical and biological engineering.

[18]  Axel Wismüller,et al.  Computer-Aided Diagnosis for Phase-Contrast X-ray Computed Tomography: Quantitative Characterization of Human Patellar Cartilage with High-Dimensional Geometric Features , 2014, Journal of Digital Imaging.

[19]  Anke Meyer-Bäse,et al.  Segmentation and classification of dynamic breast magnetic resonance image data , 2006, J. Electronic Imaging.

[20]  Kristel Michielsen,et al.  Integral-geometry morphological image analysis , 2001 .

[21]  Axel Wismüller,et al.  Computer-Aided Diagnosis in Phase Contrast Imaging X-Ray Computed Tomography for Quantitative Characterization of ex vivo Human Patellar Cartilage , 2013, IEEE Transactions on Biomedical Engineering.

[22]  S. Majumdar,et al.  Local 3D Scaling Properties for the Analysis of Trabecular Bone Extracted from High-Resolution Magnetic Resonance Imaging of Human Trabecular Bone: Comparison with Bone Mineral Density in the Prediction of Biomechanical Strength In Vitro , 2003, Investigative radiology.

[23]  Axel Wismüller A Computational Framework for Nonlinear Dimensionality Reduction and Clustering , 2009, WSOM.

[24]  Alexander J. Smola,et al.  Support Vector Regression Machines , 1996, NIPS.

[25]  Axel Wismüller,et al.  Texture feature ranking with relevance learning to classify interstitial lung disease patterns , 2012, Artif. Intell. Medicine.

[26]  Axel Wismüller,et al.  Classification of small lesions on dynamic breast MRI: Integrating dimension reduction and out-of-sample extension into CADx methodology , 2014, Artif. Intell. Medicine.

[27]  Thomas Martinetz,et al.  Medical image compression using topology-preserving neural networks , 2005, Eng. Appl. Artif. Intell..