Image-domain multimaterial decomposition for dual-energy computed tomography with nonconvex sparsity regularization

Abstract. Dual-energy computed tomography (CT) has the potential to decompose tissues into different materials. However, the classic direct inversion (DI) method for multimaterial decomposition (MMD) cannot accurately separate more than two basis materials due to the ill-posed problem and amplified image noise. We propose an integrated MMD method that addresses the piecewise smoothness and intrinsic sparsity property of the decomposition image. The proposed MMD was formulated as an optimization problem including a quadratic data fidelity term, an isotropic total variation term that encourages image smoothness, and a nonconvex penalty function that promotes decomposition image sparseness. The mass and volume conservation rule was formulated as the probability simplex constraint. An accelerated primal-dual splitting approach with line search was applied to solve the optimization problem. The proposed method with different penalty functions was compared against DI on a digital phantom, a Catphan® 600 phantom, a quantitative imaging phantom, and a pelvis patient. The proposed framework distinctly separated the CT image up to 12 basis materials plus air with high decomposition accuracy. The cross talks between two different materials are substantially reduced, as shown by the decreased nondiagonal elements of the normalized cross correlation (NCC) matrix. The mean square error of the measured electron densities was reduced by 72.6%. Across all datasets, the proposed method improved the average volume fraction accuracy from 61.2% to 99.9% and increased the diagonality of the NCC matrix from 0.73 to 0.96. Compared with DI, the proposed MMD framework improved decomposition accuracy and material separation.

[1]  Thomas Pock,et al.  A First-Order Primal-Dual Algorithm with Linesearch , 2016, SIAM J. Optim..

[2]  C. McCollough,et al.  Dual- and Multi-Energy CT: Principles, Technical Approaches, and Clinical Applications. , 2015, Radiology.

[3]  Y. H. Lee,et al.  Comparison of Virtual Unenhanced Images Derived From Dual-Energy CT With True Unenhanced Images in Evaluation of Gallstone Disease. , 2016, AJR. American journal of roentgenology.

[4]  J. P. McKelvey,et al.  Simple transcendental expressions for the roots of cubic equations , 1984 .

[5]  Rob Fergus,et al.  Fast Image Deconvolution using Hyper-Laplacian Priors , 2009, NIPS.

[6]  Stephen P. Boyd,et al.  Convex Optimization , 2004, Algorithms and Theory of Computation Handbook.

[7]  Marc Teboulle,et al.  A Fast Iterative Shrinkage-Thresholding Algorithm for Linear Inverse Problems , 2009, SIAM J. Imaging Sci..

[8]  Antonin Chambolle,et al.  A First-Order Primal-Dual Algorithm for Convex Problems with Applications to Imaging , 2011, Journal of Mathematical Imaging and Vision.

[9]  Ke Sheng,et al.  Image-domain multi-material decomposition for dual-energy CT with non-convex sparsity regularization , 2019, Medical Imaging: Image Processing.

[10]  Gaofeng Shi,et al.  Quantitative analysis of the dual-energy CT virtual spectral curve for focal liver lesions characterization. , 2014, European journal of radiology.

[11]  Daniel T Boll,et al.  Renal stone assessment with dual-energy multidetector CT and advanced postprocessing techniques: improved characterization of renal stone composition--pilot study. , 2009, Radiology.

[12]  A Macovski,et al.  Energy dependent reconstruction in X-ray computerized tomography. , 1976, Computers in biology and medicine.

[13]  A. Macovski,et al.  Energy-selective reconstructions in X-ray computerised tomography , 1976, Physics in medicine and biology.

[14]  Hirochika Suzuki Dual Energy CT in the Oncologic Applications of the Breast , 2013 .

[15]  Daniel Cremers,et al.  An algorithm for minimizing the Mumford-Shah functional , 2009, 2009 IEEE 12th International Conference on Computer Vision.

[16]  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.

[17]  Jeffrey A. Fessler,et al.  Multi-Material Decomposition Using Statistical Image Reconstruction for Spectral CT , 2014, IEEE Transactions on Medical Imaging.

[18]  Michael Möller,et al.  Low Rank Priors for Color Image Regularization , 2015, EMMCVPR.

[19]  Miguel Á. Carreira-Perpiñán,et al.  Projection onto the probability simplex: An efficient algorithm with a simple proof, and an application , 2013, ArXiv.

[20]  Paulo R. S. Mendonça,et al.  A Flexible Method for Multi-Material Decomposition of Dual-Energy CT Images , 2014, IEEE Transactions on Medical Imaging.