Low-Dose Contrast-Enhanced Breast CT Using Spectral Shaping Filters: An Experimental Study

Iodinated contrast-enhanced X-ray imaging of the breast has been studied with various modalities, including full-field digital mammography (FFDM), digital breast tomosynthesis (DBT), and dedicated breast CT. Contrast imaging with breast CT has a number of advantages over FFDM and DBT, including the lack of breast compression, and generation of fully isotropic 3-D reconstructions. Nonetheless, for breast CT to be considered as a viable tool for routine clinical use, it would be desirable to reduce radiation dose. One approach for dose reduction in breast CT is spectral shaping using X-ray filters. In this paper, two high atomic number filter materials are studied, namely, gadolinium (Gd) and erbium (Er), and compared with Al and Cu filters currently used in breast CT systems. Task-based performance is assessed by imaging a cylindrical poly(methyl methacrylate) phantom with iodine inserts on a benchtop breast CT system that emulates clinical breast CT. To evaluate detectability, a channelized hoteling observer (CHO) is used with sums of Laguerre–Gauss channels. It was observed that spectral shaping using Er and Gd filters substantially increased the dose efficiency (defined as signal-to-noise ratio of the CHO divided by mean glandular dose) as compared with kilovolt peak and filter settings used in commercial and prototype breast CT systems. These experimental phantom study results are encouraging for reducing dose of breast CT, however, further evaluation involving patients is needed.

[1]  J. H. Gallagher,et al.  Computed tomographic evaluation of the breast. , 1978, AJR. American journal of roentgenology.

[2]  Willi A Kalender,et al.  Spectral optimization for dedicated breast CT. , 2010, Medical physics.

[3]  M Gambaccini,et al.  Evaluation of the minimum iodine concentration for contrast-enhanced subtraction mammography. , 2006, Physics in medicine and biology.

[4]  Ann-Katherine Carton,et al.  Optimization of a dual-energy contrast-enhanced technique for a photon-counting digital breast tomosynthesis system: I. A theoretical model. , 2010, Medical physics.

[5]  Arthur E. Burgess Laguerre-Gauss basis functions in observer models , 2003, SPIE Medical Imaging.

[6]  Karel G M Moons,et al.  Meta-analysis of MR imaging in the diagnosis of breast lesions. , 2008, Radiology.

[7]  Ehsan Samei,et al.  Dual-energy contrast-enhanced breast tomosynthesis: optimization of beam quality for dose and image quality , 2011, Physics in medicine and biology.

[8]  Ehsan Samei,et al.  Design and development of a fully 3D dedicated x-ray computed mammotomography system , 2005, SPIE Medical Imaging.

[9]  Martin J Yaffe,et al.  Contrast-enhanced digital mammography: initial clinical experience. , 2003, Radiology.

[10]  Les Irwig,et al.  Accuracy and surgical impact of magnetic resonance imaging in breast cancer staging: systematic review and meta-analysis in detection of multifocal and multicentric cancer. , 2008, Journal of clinical oncology : official journal of the American Society of Clinical Oncology.

[11]  Christian Steiding,et al.  Technical feasibility proof for high-resolution low-dose photon-counting CT of the breast , 2017, European Radiology.

[12]  U Bick,et al.  Use of Iodine-based Contrast Media in Digital Full-field Mammography - Initial Experience , 2003, RoFo : Fortschritte auf dem Gebiete der Rontgenstrahlen und der Nuklearmedizin.

[13]  John M. Boone,et al.  Computed Tomography for Imaging the Breast , 2006, Journal of Mammary Gland Biology and Neoplasia.

[14]  John M Boone,et al.  Contrast-enhanced dedicated breast CT: initial clinical experience. , 2010, Radiology.

[15]  Giovanni Mettivier,et al.  Dedicated breast computed tomography: Basic aspects. , 2015, Medical physics.

[16]  H H Barrett,et al.  Addition of a channel mechanism to the ideal-observer model. , 1987, Journal of the Optical Society of America. A, Optics and image science.

[17]  John M Boone,et al.  Experimentally determined spectral optimization for dedicated breast computed tomography. , 2011, Medical physics.

[18]  Hyo-Min Cho,et al.  Characteristic performance evaluation of a photon counting Si strip detector for low dose spectral breast CT imaging. , 2014, Medical physics.

[19]  Stephen J Glick,et al.  Breast CT. , 2007, Annual review of biomedical engineering.

[20]  Samta Thacker,et al.  Evaluating the impact of X-ray spectral shape on image quality in flat-panel CT breast imaging. , 2007, Medical physics.

[21]  Ann-Katherine Carton,et al.  Dual-energy subtraction for contrast-enhanced digital breast tomosynthesis , 2007, SPIE Medical Imaging.

[22]  Huiguang He,et al.  Preliminary system characterization of flat-panel-detector-based cone-beam CT for breast imaging , 2004, SPIE Medical Imaging.

[23]  Mehran Ebrahimi,et al.  Anatomical noise in contrast-enhanced digital mammography. Part I. Single-energy imaging. , 2013, Medical physics.

[24]  Loren Niklason,et al.  Advanced applications of digital mammography: tomosynthesis and contrast-enhanced digital mammography. , 2007, Seminars in roentgenology.

[25]  S. Evans Catalogue of Diagnostic X-Ray Spectra and Other Data , 1998 .

[26]  Stephen J. Glick,et al.  Investigation of statistical iterative reconstruction for dedicated breast CT , 2012, Medical Imaging.

[27]  J. Boone,et al.  Dedicated breast CT: radiation dose and image quality evaluation. , 2001, Radiology.

[28]  Shiva Abbaszadeh,et al.  Evaluating noise reduction techniques while considering anatomical noise in dual-energy contrast-enhanced mammography. , 2013, Medical physics.

[29]  Michael Sandborg,et al.  A search for optimal x-ray spectra in iodine contrast media mammography. , 2005, Physics in medicine and biology.

[30]  Ann-Katherine Carton,et al.  Optimization of a dual-energy contrast-enhanced technique for a photon-counting digital breast tomosynthesis system: II. An experimental validation. , 2010, Medical physics.

[31]  Anita Nosratieh,et al.  Differentiation of ductal carcinoma in-situ from benign micro-calcifications by dedicated breast computed tomography. , 2016, European journal of radiology.

[32]  Nooshin Kiarashi,et al.  Task-based strategy for optimized contrast enhanced breast imaging: analysis of six imaging techniques for mammography and tomosynthesis. , 2014, Medical physics.

[33]  S J Dwyer,et al.  Specific value of computed tomographic breast scanner (CT/M) in diagnosis of breast diseases. , 1979, Radiology.

[34]  Serge Muller,et al.  Digital Mammography Using Iodine-Based Contrast Media: Initial Clinical Experience With Dynamic Contrast Medium Enhancement , 2005, Investigative radiology.

[35]  Andrey Makeev,et al.  Investigation of x-ray spectra for iodinated contrast-enhanced dedicated breast CT , 2017, Journal of medical imaging.

[36]  Serge Muller,et al.  Development of contrast digital mammography. , 2002, Medical physics.

[37]  Michaela C. C. Weigel,et al.  High-resolution spiral CT of the breast at very low dose: concept and feasibility considerations , 2011, European Radiology.

[38]  Srinivasan Vedantham,et al.  Personalized estimates of radiation dose from dedicated breast CT in a diagnostic population and comparison with diagnostic mammography , 2013, Physics in medicine and biology.