Computer-aided detection of masses in digital tomosynthesis mammography: comparison of three approaches.

The authors are developing a computer-aided detection (CAD) system for masses on digital breast tomosynthesis mammograms (DBT). Three approaches were evaluated in this study. In the first approach, mass candidate identification and feature analysis are performed in the reconstructed three-dimensional (3D) DBT volume. A mass likelihood score is estimated for each mass candidate using a linear discriminant analysis (LDA) classifier. Mass detection is determined by a decision threshold applied to the mass likelihood score. A free response receiver operating characteristic (FROC) curve that describes the detection sensitivity as a function of the number of false positives (FPs) per breast is generated by varying the decision threshold over a range. In the second approach, prescreening of mass candidate and feature analysis are first performed on the individual two-dimensional (2D) projection view (PV) images. A mass likelihood score is estimated for each mass candidate using an LDA classifier trained for the 2D features. The mass likelihood images derived from the PVs are backprojected to the breast volume to estimate the 3D spatial distribution of the mass likelihood scores. The FROC curve for mass detection can again be generated by varying the decision threshold on the 3D mass likelihood scores merged by backprojection. In the third approach, the mass likelihood scores estimated by the 3D and 2D approaches, described above, at the corresponding 3D location are combined and evaluated using FROC analysis. A data set of 100 DBT cases acquired with a GE prototype system at the Breast Imaging Laboratory in the Massachusetts General Hospital was used for comparison of the three approaches. The LDA classifiers with stepwise feature selection were designed with leave-one-case-out resampling. In FROC analysis, the CAD system for detection in the DBT volume alone achieved test sensitivities of 80% and 90% at average FP rates of 1.94 and 3.40 per breast, respectively. With the 2D detection approach, the FP rates were 2.86 and 4.05 per breast, respectively, at the corresponding sensitivities. In comparison, the average FP rates of the system combining the 3D and 2D information were 1.23 and 2.04 per breast, respectively, at 80% and 90% sensitivities. The difference in the detection performances between the 2D and the 3D approach, and that between the 3D and the combined approach were both statistically significant (p = 0.02 and 0.01, respectively) as estimated by alternative FROC analysis. The combined system is a promising approach to improving automated mass detection on DBTs.

[1]  Berkman Sahiner,et al.  Computer-aided detection system for breast masses on digital tomosynthesis mammograms: preliminary experience. , 2005, Radiology.

[2]  Berkman Sahiner,et al.  Classification of malignant and benign masses based on hybrid ART2LDA approach , 1999, IEEE Transactions on Medical Imaging.

[3]  Berkman Sahiner,et al.  Lung nodule detection on thoracic computed tomography images: preliminary evaluation of a computer-aided diagnosis system. , 2002, Medical physics.

[4]  Mary M. Galloway,et al.  Texture analysis using gray level run lengths , 1974 .

[5]  Berkman Sahiner,et al.  Computer-aided detection systems for breast masses: comparison of performances on full-field digital mammograms and digitized screen-film mammograms. , 2007, Academic radiology.

[6]  Berkman Sahiner,et al.  Computer-aided detection of breast masses on full field digital mammograms. , 2005, Medical physics.

[7]  D. Chakraborty,et al.  Free-response methodology: alternate analysis and a new observer-performance experiment. , 1990, Radiology.

[8]  N. Petrick,et al.  Computerized characterization of masses on mammograms: the rubber band straightening transform and texture analysis. , 1998, Medical physics.

[9]  B Sahiner,et al.  False-positive reduction technique for detection of masses on digital mammograms: global and local multiresolution texture analysis. , 1997, Medical physics.

[10]  K Doi,et al.  Improvement in radiologists' detection of clustered microcalcifications on mammograms. The potential of computer-aided diagnosis. , 1990, Investigative radiology.

[11]  Lubomir M. Hadjiiski,et al.  A comparative study of limited-angle cone-beam reconstruction methods for breast tomosynthesis. , 2006, Medical physics.

[12]  Berkman Sahiner,et al.  Computer-aided detection of masses in digital tomosynthesis mammography: combination of 3D and 2D detection information , 2007, SPIE Medical Imaging.

[13]  Berkman Sahiner,et al.  Dual system approach to computer-aided detection of breast masses on mammograms. , 2006, Medical physics.

[14]  T. Freer,et al.  Screening mammography with computer-aided detection: prospective study of 12,860 patients in a community breast center. , 2001, Radiology.

[15]  Lubomir M. Hadjiiski,et al.  Feature selection and classifier performance in computer-aided diagnosis: the effect of finite sample size. , 2000, Medical physics.

[16]  M L Giger,et al.  Computerized Detection of Mass Lesions in Digital Breast Tomosynthesis Images Using Two- and Three Dimensional Radial Gradient Index Segmentation , 2004, Technology in cancer research & treatment.

[17]  M. Giger,et al.  Computerized mass detection for digital breast tomosynthesis directly from the projection images. , 2006, Medical physics.

[18]  Tor D Tosteson,et al.  Digital breast tomosynthesis: initial experience in 98 women with abnormal digital screening mammography. , 2007, AJR. American journal of roentgenology.

[19]  Kee Tung. Wong,et al.  Texture features for image classification and retrieval. , 2002 .

[20]  Berkman Sahiner,et al.  Sensitivity of noncommercial computer-aided detection system for mammographic breast cancer detection: pilot clinical trial. , 2004, Radiology.

[22]  R. Bird,et al.  Analysis of cancers missed at screening mammography. , 1992, Radiology.