A general framework of noise suppression in material decomposition for dual-energy CT.

PURPOSE As a general problem of dual-energy CT (DECT), noise amplification in material decomposition severely reduces the signal-to-noise ratio on the decomposed images compared to that on the original CT images. In this work, the authors propose a general framework of noise suppression in material decomposition for DECT. The method is based on an iterative algorithm recently developed in their group for image-domain decomposition of DECT, with an extension to include nonlinear decomposition models. The generalized framework of iterative DECT decomposition enables beam-hardening correction with simultaneous noise suppression, which improves the clinical benefits of DECT. METHODS The authors propose to suppress noise on the decomposed images of DECT using convex optimization, which is formulated in the form of least-squares estimation with smoothness regularization. Based on the design principles of a best linear unbiased estimator, the authors include the inverse of the estimated variance-covariance matrix of the decomposed images as the penalty weight in the least-squares term. Analytical formulas are derived to compute the variance-covariance matrix for decomposed images with general-form numerical or analytical decomposition. As a demonstration, the authors implement the proposed algorithm on phantom data using an empirical polynomial function of decomposition measured on a calibration scan. The polynomial coefficients are determined from the projection data acquired on a wedge phantom, and the signal decomposition is performed in the projection domain. RESULTS On the Catphan(®)600 phantom, the proposed noise suppression method reduces the average noise standard deviation of basis material images by one to two orders of magnitude, with a superior performance on spatial resolution as shown in comparisons of line-pair images and modulation transfer function measurements. On the synthesized monoenergetic CT images, the noise standard deviation is reduced by a factor of 2-3. By using nonlinear decomposition on projections, the authors' method effectively suppresses the streaking artifacts of beam hardening and obtains more uniform images than their previous approach based on a linear model. Similar performance of noise suppression is observed in the results of an anthropomorphic head phantom and a pediatric chest phantom generated by the proposed method. With beam-hardening correction enabled by their approach, the image spatial nonuniformity on the head phantom is reduced from around 10% on the original CT images to 4.9% on the synthesized monoenergetic CT image. On the pediatric chest phantom, their method suppresses image noise standard deviation by a factor of around 7.5, and compared with linear decomposition, it reduces the estimation error of electron densities from 33.3% to 8.6%. CONCLUSIONS The authors propose a general framework of noise suppression in material decomposition for DECT. Phantom studies have shown the proposed method improves the image uniformity and the accuracy of electron density measurements by effective beam-hardening correction and reduces noise level without noticeable resolution loss.

[1]  Lei Zhu,et al.  Low-Dose and Scatter-Free Cone-Beam CT Imaging Using a Stationary Beam Blocker in a Single Scan: Phantom Studies , 2013, Comput. Math. Methods Medicine.

[2]  A. Macovski,et al.  Measurement-Dependent Filtering: A Novel Approach to Improved SNR , 1983, IEEE Transactions on Medical Imaging.

[3]  Xiaojing Ye,et al.  Accelerated barrier optimization compressed sensing (ABOCS) for CT reconstruction with improved convergence. , 2014, Physics in medicine and biology.

[4]  Lei Zhu,et al.  Iterative image-domain decomposition for dual-energy CT. , 2014, Medical physics.

[5]  R. Alvarez Dimensionality and noise in energy selective x-ray imaging. , 2013, Medical physics.

[6]  Lei Zhu,et al.  Shading correction for on-board cone-beam CT in radiation therapy using planning MDCT images. , 2010, Medical physics.

[7]  128-Slice Acceletated-Pitch Dual Energy CT Angiography of the Head and Neck: Comparison of Different Low Contrast Medium Volumes , 2013, PloS one.

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

[9]  W. Kalender,et al.  An algorithm for noise suppression in dual energy CT material density images. , 1988, IEEE transactions on medical imaging.

[10]  C. McCollough,et al.  Virtual monochromatic imaging in dual-source dual-energy CT: radiation dose and image quality. , 2011, Medical physics.

[11]  M. Oudkerk,et al.  Dual-energy CT of the heart. , 2012, AJR. American journal of roentgenology.

[12]  Lei Zhu,et al.  Quantitative cone-beam CT imaging in radiation therapy using planning CT as a prior: first patient studies. , 2012, Medical physics.

[13]  Luo Ouyang,et al.  Noise correlation in CBCT projection data and its application for noise reduction in low-dose CBCT. , 2014, Medical physics.

[14]  James T Dobbins,et al.  Quantitative , 2020, Psychology through Critical Auto-Ethnography.

[15]  M. Macari,et al.  Dual energy CT: preliminary observations and potential clinical applications in the abdomen , 2008, European Radiology.

[16]  Lei Zhu,et al.  Combined iterative reconstruction and image-domain decomposition for dual energy CT using total-variation regularization. , 2014, Medical physics.

[17]  K. Deng,et al.  Clinical evaluation of dual-energy bone removal in CT angiography of the head and neck: comparison with conventional bone-subtraction CT angiography. , 2009, Clinical radiology.

[18]  N. R. Bennett,et al.  Scatter correction method for x-ray CT using primary modulation: phantom studies. , 2010, Medical physics.

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

[20]  Tianye Niu,et al.  Single-scan energy-selective imaging on cone-beam CT: a preliminary study , 2013, Medical Imaging.

[21]  James T. Dobbins,et al.  Recent progress in noise reduction and scatter correction in dual-energy imaging , 1995, Medical Imaging.

[22]  Timo Berkus,et al.  Empirical dual energy calibration (EDEC) for cone-beam computed tomography. , 2007 .

[23]  A Fenster,et al.  An accurate method for direct dual-energy calibration and decomposition. , 1990, Medical physics.

[24]  Adam Wunderlich,et al.  Image covariance and lesion detectability in direct fan-beam x-ray computed tomography , 2008, Physics in medicine and biology.

[25]  M A Karim,et al.  Optical symbolic substitution: edge detection using Prewitt, Sobel, and Roberts operators. , 1989, Applied optics.

[26]  Daniele Marin,et al.  State of the art: dual-energy CT of the abdomen. , 2014, Radiology.

[27]  Diagnostic value of Flash dual-source CT coronary artery imaging combined with dual-energy myocardial perfusion imaging for coronary heart disease , 2014, Experimental and therapeutic medicine.

[28]  John F. Canny,et al.  A Computational Approach to Edge Detection , 1986, IEEE Transactions on Pattern Analysis and Machine Intelligence.

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

[30]  Lei Zhu,et al.  Accelerated barrier optimization compressed sensing (ABOCS) reconstruction for cone-beam CT: Phantom studies. , 2012, Medical physics.

[31]  Xiaochuan Pan,et al.  Impact of polychromatic x-ray sources on helical, cone-beam computed tomography and dual-energy methods. , 2004, Physics in medicine and biology.

[32]  Lei Zhu,et al.  A practical reconstruction algorithm for CT noise variance maps using FBP reconstruction , 2007, SPIE Medical Imaging.

[33]  Thomas Henzler,et al.  Dual-energy CT: radiation dose aspects. , 2012, AJR. American journal of roentgenology.

[34]  Jiang Hsieh,et al.  Image quality evaluation of iterative CT reconstruction algorithms: a perspective from spatial domain noise texture measures , 2012, Medical Imaging.

[35]  Konstantin Nikolaou,et al.  Dual Energy CT of the Chest: How About the Dose? , 2010, Investigative radiology.

[36]  U. Schoepf,et al.  Dual-energy CT imaging of thoracic malignancies , 2013, Cancer imaging : the official publication of the International Cancer Imaging Society.

[37]  Dushyant V. Sahani,et al.  Oncologic applications of dual-energy CT in the abdomen. , 2014, Radiographics : a review publication of the Radiological Society of North America, Inc.

[38]  M. Kachelriess,et al.  Exact dual energy material decomposition from inconsistent rays (MDIR). , 2011, Medical physics.