X-ray scatter correction method for dedicated breast computed tomography.

PURPOSE To improve image quality and accuracy in dedicated breast computed tomography (BCT) by removing the x-ray scatter signal included in the BCT projections. METHODS The previously characterized magnitude and distribution of x-ray scatter in BCT results in both cupping artifacts and reduction of contrast and accuracy in the reconstructions. In this study, an image processing method is proposed that estimates and subtracts the low-frequency x-ray scatter signal included in each BCT projection postacquisition and prereconstruction. The estimation of this signal is performed using simple additional hardware, one additional BCT projection acquisition with negligible radiation dose, and simple image processing software algorithms. The high frequency quantum noise due to the scatter signal is reduced using a noise filter postreconstruction. The dosimetric consequences and validity of the assumptions of this algorithm were determined using Monte Carlo simulations. The feasibility of this method was determined by imaging a breast phantom on a BCT clinical prototype and comparing the corrected reconstructions to the unprocessed reconstructions and to reconstructions obtained from fan-beam acquisitions as a reference standard. One-dimensional profiles of the reconstructions and objective image quality metrics were used to determine the impact of the algorithm. RESULTS The proposed additional acquisition results in negligible additional radiation dose to the imaged breast (∼0.4% of the standard BCT acquisition). The processed phantom reconstruction showed substantially reduced cupping artifacts, increased contrast between adipose and glandular tissue equivalents, higher voxel value accuracy, and no discernible blurring of high frequency features. CONCLUSIONS The proposed scatter correction method for dedicated breast CT is feasible and can result in highly improved image quality. Further optimization and testing, especially with patient images, is necessary to characterize its impact on clinical performance.

[1]  T R Nelson,et al.  A comprehensive analysis of DgN(CT) coefficients for pendant-geometry cone-beam breast computed tomography. , 2004, Medical physics.

[2]  Polad M Shikhaliev,et al.  Beam hardening artefacts in computed tomography with photon counting, charge integrating and energy weighting detectors: a simulation study , 2005, Physics in medicine and biology.

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

[4]  S. Incerti,et al.  Geant4 developments and applications , 2006, IEEE Transactions on Nuclear Science.

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

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

[7]  J. Dinten,et al.  A new method for x-ray scatter correction: first assessment on a cone-beam CT experimental setup , 2007, Physics in medicine and biology.

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

[9]  Ruola Ning,et al.  X-ray scatter correction algorithm for cone beam CT imaging. , 2004, Medical physics.

[10]  M. Endo,et al.  Effect of scattered radiation on image noise in cone beam CT. , 2001, Medical physics.

[11]  D. Shepard A two-dimensional interpolation function for irregularly-spaced data , 1968, ACM National Conference.

[12]  K. Kerlikowske,et al.  Effect of age, breast density, and family history on the sensitivity of first screening mammography. , 1996, JAMA.

[13]  Stephen J. Glick,et al.  Characterization of scatter radiation in cone beam CT mammography , 2005, SPIE Medical Imaging.

[14]  Freek J. Beekman,et al.  Efficient Monte Carlo based scatter artifact reduction in cone-beam micro-CT , 2006, IEEE Transactions on Medical Imaging.

[15]  Ioannis Sechopoulos,et al.  Dosimetric characterization of a dedicated breast computed tomography clinical prototype. , 2010, Medical physics.

[16]  X Liu,et al.  A post-reconstruction method to correct cupping artifacts in cone beam breast computed tomography. , 2007, Medical physics.

[17]  Lei Zhu,et al.  Scatter Correction Method for X-Ray CT Using Primary Modulation: Theory and Preliminary Results , 2006, IEEE Transactions on Medical Imaging.

[18]  Ioannis Sechopoulos,et al.  Clinical digital breast tomosynthesis system: dosimetric characterization. , 2012, Radiology.

[19]  D. Jaffray,et al.  The influence of antiscatter grids on soft-tissue detectability in cone-beam computed tomography with flat-panel detectors. , 2004, Medical physics.

[20]  Lei Zhu,et al.  Scatter correction for full-fan volumetric CT using a stationary beam blocker in a single full scan. , 2011, Medical physics.

[21]  Ning Wen,et al.  Combining scatter reduction and correction to improve image quality in cone-beam computed tomography (CBCT). , 2010, Medical physics.

[22]  Aruna A. Vedula,et al.  A computer simulation study comparing lesion detection accuracy with digital mammography, breast tomosynthesis, and cone-beam CT breast imaging. , 2006, Medical physics.

[23]  Yong Yu,et al.  A novel cone beam breast CT scanner: system evaluation , 2007, SPIE Medical Imaging.

[24]  Ruola Ning,et al.  Flat-panel-detector-based cone-beam volume CT breast imaging: phantom and specimen study , 2002, SPIE Medical Imaging.

[25]  W. Kalender,et al.  Combining deterministic and Monte Carlo calculations for fast estimation of scatter intensities in CT , 2006, Physics in medicine and biology.

[26]  Matthias Bertram,et al.  Model based scatter correction for cone-beam computed tomography , 2005, SPIE Medical Imaging.

[27]  Ruola Ning,et al.  X-ray scatter suppression algorithm for cone-beam volume CT , 2002, SPIE Medical Imaging.

[28]  T. M. Kolb,et al.  Comparison of the performance of screening mammography, physical examination, and breast US and evaluation of factors that influence them: an analysis of 27,825 patient evaluations. , 2002, Radiology.

[29]  Ruola Ning,et al.  Image denoising based on multiscale singularity detection for cone beam CT breast imaging , 2004, IEEE Transactions on Medical Imaging.

[30]  Lei Xing,et al.  Improved scatter correction for x-ray conebeam CT using primary modulation , 2007, SPIE Medical Imaging.

[31]  J. Boone,et al.  Dedicated breast CT: initial clinical experience. , 2008, Radiology.

[32]  Radhe Mohan,et al.  Scatter kernel estimation with an edge-spread function method for cone-beam computed tomography imaging , 2008, Physics in medicine and biology.

[33]  M J Yaffe,et al.  The myth of the 50-50 breast. , 2009, Medical physics.

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

[35]  C. D'Orsi,et al.  Monte Carlo and phantom study of the radiation dose to the body from dedicated CT of the breast. , 2008, Radiology.

[36]  Tianpeng Wang,et al.  An accurate scatter measurement and correction technique for cone beam breast CT imaging using scanning sampled measurement (SSM)technique , 2006, SPIE Medical Imaging.

[37]  Taly Gilat Schmidt,et al.  Simulated scatter performance of an inverse-geometry dedicated breast CT system. , 2009, Medical physics.

[38]  T Bortfeld,et al.  Correction of scatter in megavoltage cone-beam CT , 2001, Physics in medicine and biology.

[39]  James G. Nagy,et al.  Numerical Algorithms for Polyenergetic Digital Breast Tomosynthesis Reconstruction , 2010, SIAM J. Imaging Sci..

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

[41]  S. Richard,et al.  A simple, direct method for x-ray scatter estimation and correction in digital radiography and cone-beam CT. , 2005, Medical physics.

[42]  Lei Zhu,et al.  Noise suppression in scatter correction for cone-beam CT. , 2009, Medical physics.

[43]  I. Sechopoulos,et al.  SU‐FF‐I‐12: Validation of Geant4's Predictions On X‐Ray Scatter and Glandular Dose in Pendant‐Geometry Cone‐Beam Breast CT , 2006 .

[44]  J. Boone,et al.  Evaluation of x-ray scatter properties in a dedicated cone-beam breast CT scanner. , 2005, Medical physics.

[45]  Masatoshi Saito,et al.  Dual-energy approach to contrast-enhanced mammography using the balanced filter method: spectral optimization and preliminary phantom measurement. , 2007, Medical physics.

[46]  Ruola Ning,et al.  Investigation into the influence of x-ray scatter on the imaging performance of an x-ray flat-panel imager-based cone-beam volume CT , 2001, SPIE Medical Imaging.

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

[48]  Lei Zhu,et al.  X-ray scatter correction for cone-beam CT using moving blocker array , 2005, SPIE Medical Imaging.