Optimal reconstruction and quantitative image features for computer‐aided diagnosis tools for breast CT

Purpose The purpose of this study is to determine the optimal representative reconstruction and quantitative image feature set for a computer‐aided diagnosis (CADx) scheme for dedicated breast computer tomography (bCT). Method We used 93 bCT scans that contain 102 breast lesions (62 malignant, 40 benign). Using an iterative image reconstruction (IIR) algorithm, we created 37 reconstructions with different image appearances for each case. In addition, we added a clinical reconstruction for comparison purposes. We used image sharpness, determined by the gradient of gray value in a parenchymal portion of the reconstructed breast, as a surrogate measure of the image qualities/appearances for the 38 reconstructions. After segmentation of the breast lesion, we extracted 23 quantitative image features. Using leave‐one‐out‐cross‐validation (LOOCV), we conducted the feature selection, classifier training, and testing. For this study, we used the linear discriminant analysis classifier. Then, we selected the representative reconstruction and feature set for the classifier with the best diagnostic performance among all reconstructions and feature sets. Then, we conducted an observer study with six radiologists using a subset of breast lesions (N = 50). Using 1000 bootstrap samples, we compared the diagnostic performance of the trained classifier to those of the radiologists. Result The diagnostic performance of the trained classifier increased as the image sharpness of a given reconstruction increased. Among combinations of reconstructions and quantitative image feature sets, we selected one of the sharp reconstructions and three quantitative image feature sets with the first three highest diagnostic performances under LOOCV as the representative reconstruction and feature set for the classifier. The classifier on the representative reconstruction and feature set achieved better diagnostic performance with an area under the ROC curve (AUC) of 0.94 (95% CI = [0.81, 0.98]) than those of the radiologists, where their maximum AUC was 0.78 (95% CI = [0.63, 0.90]). Moreover, the partial AUC, at 90% sensitivity or higher, of the classifier (pAUC = 0.085 with 95% CI = [0.063, 0.094]) was statistically better (P‐value < 0.0001) than those of the radiologists (maximum pAUC = 0.009 with 95% CI = [0.003, 0.024]). Conclusion We found that image sharpness measure can be a good candidate to estimate the diagnostic performance of a given CADx algorithm. In addition, we found that there exists a reconstruction (i.e., sharp reconstruction) and a feature set that maximizes the diagnostic performance of a CADx algorithm. On this optimal representative reconstruction and feature set, the CADx algorithm outperformed radiologists.

[1]  Ingrid Reiser,et al.  Local curvature analysis for classifying breast tumors: Preliminary analysis in dedicated breast CT. , 2015, Medical physics.

[2]  Benoit M. Dawant,et al.  Morphometric analysis of white matter lesions in MR images: method and validation , 1994, IEEE Trans. Medical Imaging.

[3]  Robert M. Nishikawa,et al.  WE‐G‐207‐05: Relationship Between CT Image Quality, Segmentation Performance, and Quantitative Image Feature Analysis , 2015 .

[4]  Maryellen L. Giger,et al.  Automated seeded lesion segmentation on digital mammograms , 1998, IEEE Transactions on Medical Imaging.

[5]  M. Su,et al.  Evaluation of Clinical Breast MR Imaging Performed with Prototype Computer-aided Diagnosis Breast MR Imaging Workstation: Reader Study , 2012 .

[6]  R. Tibshirani,et al.  Improvements on Cross-Validation: The 632+ Bootstrap Method , 1997 .

[7]  M. Elter,et al.  CADx of mammographic masses and clustered microcalcifications: a review. , 2009, Medical physics.

[8]  Robert M. Nishikawa,et al.  Can model observers be developed to reproduce radiologists' diagnostic performances? Our study says not so fast! , 2016, SPIE Medical Imaging.

[9]  M. Giger,et al.  Malignant and benign clustered microcalcifications: automated feature analysis and classification. , 1996, Radiology.

[10]  D. McClish Analyzing a Portion of the ROC Curve , 1989, Medical decision making : an international journal of the Society for Medical Decision Making.

[11]  Robert M. Nishikawa,et al.  Evaluation of a 3D lesion segmentation algorithm on DBT and breast CT images , 2010, Medical Imaging.

[12]  C. D'Orsi,et al.  Dedicated breast computed tomography: the optimal cross-sectional imaging solution? , 2010, Radiologic clinics of North America.

[13]  John M. Boone,et al.  Analysis of breast CT lesions using computer-aided diagnosis: an application of neural networks on extracted morphologic and texture features , 2012, Medical Imaging.

[14]  L. R. Dice Measures of the Amount of Ecologic Association Between Species , 1945 .

[15]  C. Metz,et al.  A receiver operating characteristic partial area index for highly sensitive diagnostic tests. , 1996, Radiology.

[16]  F. Samuelson,et al.  The average receiver operating characteristic curve in multireader multicase imaging studies. , 2014, The British journal of radiology.

[17]  Rangaraj M. Rangayyan,et al.  A review of computer-aided diagnosis of breast cancer: Toward the detection of subtle signs , 2007, J. Frankl. Inst..

[18]  Karen Drukker,et al.  Impact of lesion segmentation metrics on computer-aided diagnosis/detection in breast computed tomography , 2014, Journal of medical imaging.

[19]  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.

[20]  Emil Y. Sidky,et al.  Efficient iterative image reconstruction algorithm for dedicated breast CT , 2016, SPIE Medical Imaging.

[21]  Axel Wismüller,et al.  Investigating the use of texture features for analysis of breast lesions on contrast-enhanced cone beam CT , 2014, Medical Imaging.

[22]  L. Feldkamp,et al.  Practical cone-beam algorithm , 1984 .

[23]  P. Taylor,et al.  A systematic review of computer-assisted diagnosis in diagnostic cancer imaging. , 2012, European journal of radiology.

[24]  Kunio Doi,et al.  Computer-aided diagnosis in medical imaging: Historical review, current status and future potential , 2007, Comput. Medical Imaging Graph..