Common-mask guided image reconstruction (c-MGIR) for enhanced 4D cone-beam computed tomography

Compared to 3D cone beam computed tomography (3D CBCT), the image quality of commercially available four-dimensional (4D) CBCT is severely impaired due to the insufficient amount of projection data available for each phase. Since the traditional Feldkamp-Davis-Kress (FDK)-based algorithm is infeasible for reconstructing high quality 4D CBCT images with limited projections, investigators had developed several compress-sensing (CS) based algorithms to improve image quality. The aim of this study is to develop a novel algorithm which can provide better image quality than the FDK and other CS based algorithms with limited projections. We named this algorithm 'the common mask guided image reconstruction' (c-MGIR).In c-MGIR, the unknown CBCT volume is mathematically modeled as a combination of phase-specific motion vectors and phase-independent static vectors. The common-mask matrix, which is the key concept behind the c-MGIR algorithm, separates the common static part across all phase images from the possible moving part in each phase image. The moving part and the static part of the volumes were then alternatively updated by solving two sub-minimization problems iteratively. As the novel mathematical transformation allows the static volume and moving volumes to be updated (during each iteration) with global projections and 'well' solved static volume respectively, the algorithm was able to reduce the noise and under-sampling artifact (an issue faced by other algorithms) to the maximum extent. To evaluate the performance of our proposed c-MGIR, we utilized imaging data from both numerical phantoms and a lung cancer patient. The qualities of the images reconstructed with c-MGIR were compared with (1) standard FDK algorithm, (2) conventional total variation (CTV) based algorithm, (3) prior image constrained compressed sensing (PICCS) algorithm, and (4) motion-map constrained image reconstruction (MCIR) algorithm, respectively. To improve the efficiency of the algorithm, the code was implemented with a graphic processing unit for parallel processing purposes.Root mean square error (RMSE) between the ground truth and reconstructed volumes of the numerical phantom were in the descending order of FDK, CTV, PICCS, MCIR, and c-MGIR for all phases. Specifically, the means and the standard deviations of the RMSE of FDK, CTV, PICCS, MCIR and c-MGIR for all phases were 42.64  ±  6.5%, 3.63  ±  0.83%, 1.31%  ±  0.09%, 0.86%  ±  0.11% and 0.52 %  ±  0.02%, respectively. The image quality of the patient case also indicated the superiority of c-MGIR compared to other algorithms.The results indicated that clinically viable 4D CBCT images can be reconstructed while requiring no more projection data than a typical clinical 3D CBCT scan. This makes c-MGIR a potential online reconstruction algorithm for 4D CBCT, which can provide much better image quality than other available algorithms, while requiring less dose and potentially less scanning time.

[1]  Jie Tang,et al.  Tomosynthesis via total variation minimization reconstruction and prior image constrained compressed sensing (PICCS) on a C-arm system , 2008, SPIE Medical Imaging.

[2]  Nicole M Wink,et al.  Respiratory correlated cone-beam computed tomography on an isocentric C-arm , 2005, Physics in medicine and biology.

[3]  Fang-Fang Yin,et al.  Dosimetric feasibility of cone-beam CT-based treatment planning compared to CT-based treatment planning. , 2006, International journal of radiation oncology, biology, physics.

[4]  Jan-Jakob Sonke,et al.  Frameless stereotactic body radiotherapy for lung cancer using four-dimensional cone beam CT guidance. , 2009, International journal of radiation oncology, biology, physics.

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

[6]  Bo Lu,et al.  A comprehensive study on decreasing the kilovoltage cone‐beam CT dose by reducing the projection number , 2010, Journal of applied clinical medical physics.

[7]  Jan-Jakob Sonke,et al.  Method comparison of automated matching software-assisted cone-beam CT and stereoscopic kilovoltage x-ray positional verification image-guided radiation therapy for head and neck cancer: a prospective analysis , 2009, Physics in medicine and biology.

[8]  J Trzasko,et al.  Nonconvex prior image constrained compressed sensing (NCPICCS): theory and simulations on perfusion CT. , 2011, Medical physics.

[9]  M. Kachelriess,et al.  An investigation of 4D cone-beam CT algorithms for slowly rotating scanners. , 2010, Medical physics.

[10]  Guang-Hong Chen,et al.  Streaking artifacts reduction in four-dimensional cone-beam computed tomography. , 2008, Medical physics.

[11]  T. Pan,et al.  Autoadaptive phase-correlated (AAPC) reconstruction for 4D CBCT. , 2009, Medical physics.

[12]  K. Rosenzweig,et al.  Correction of motion artifacts in cone-beam CT using a patient-specific respiratory motion model. , 2010, Medical physics.

[13]  M. V. van Herk,et al.  Respiratory correlated cone beam CT. , 2005, Medical physics.

[14]  M. Vannier,et al.  Why do commercial CT scanners still employ traditional, filtered back-projection for image reconstruction? , 2009, Inverse problems.

[15]  K. Rosenzweig,et al.  Correction of motion artifacts in cone-beam CT using a patient-specific respiratory motion model. , 2010, Medical physics.

[16]  Guang-Hong Chen,et al.  Characterization of statistical prior image constrained compressed sensing (PICCS): II. Application to dose reduction. , 2013, Medical physics.

[17]  D. Jaffray,et al.  Advances in image-guided radiation therapy. , 2007, Journal of clinical oncology : official journal of the American Society of Clinical Oncology.

[18]  Xun Jia,et al.  Four-dimensional cone beam CT reconstruction and enhancement using a temporal nonlocal means method. , 2012, Medical physics.

[19]  Lei Zhu,et al.  Search for IMRT inverse plans with piecewise constant fluence maps using compressed sensing techniques. , 2009, Medical physics.

[20]  T Kron,et al.  The effect of irregular breathing patterns on internal target volumes in four-dimensional CT and cone-beam CT images in the context of stereotactic lung radiotherapy. , 2013, Medical physics.

[21]  J. Wong,et al.  Flat-panel cone-beam computed tomography for image-guided radiation therapy. , 2002, International journal of radiation oncology, biology, physics.

[22]  J. Borwein,et al.  Two-Point Step Size Gradient Methods , 1988 .

[23]  Steve B. Jiang,et al.  Liver motion during cone beam computed tomography guided stereotactic body radiation therapy. , 2012, Medical physics.

[24]  Feng Xu,et al.  Detection of intrafractional tumour position error in radiotherapy utilizing cone beam computed tomography. , 2008, Radiotherapy and oncology : journal of the European Society for Therapeutic Radiology and Oncology.

[25]  David A Jaffray,et al.  Emergent technologies for 3-dimensional image-guided radiation delivery. , 2005, Seminars in radiation oncology.

[26]  Andrea Bezjak,et al.  Cone-beam computed tomographic image guidance for lung cancer radiation therapy. , 2009, International journal of radiation oncology, biology, physics.

[27]  Mário A. T. Figueiredo,et al.  Gradient Projection for Sparse Reconstruction: Application to Compressed Sensing and Other Inverse Problems , 2007, IEEE Journal of Selected Topics in Signal Processing.

[28]  Hideomi Yamashita,et al.  4D registration and 4D verification of lung tumor position for stereotactic volumetric modulated arc therapy using respiratory-correlated cone-beam CT , 2012, Journal of radiation research.

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

[30]  S. Leng,et al.  High temporal resolution and streak-free four-dimensional cone-beam computed tomography , 2008, Physics in medicine and biology.

[31]  Guang-Hong Chen,et al.  Characterization of statistical prior image constrained compressed sensing. I. Applications to time-resolved contrast-enhanced CT. , 2012, Medical physics.

[32]  Jie Tang,et al.  Prior image constrained compressed sensing (PICCS): a method to accurately reconstruct dynamic CT images from highly undersampled projection data sets. , 2008, Medical physics.

[33]  Jin Sung Kim,et al.  Motion-map constrained image reconstruction (MCIR): application to four-dimensional cone-beam computed tomography. , 2013, Medical physics.

[34]  Jie Tang,et al.  Performance comparison between total variation (TV)-based compressed sensing and statistical iterative reconstruction algorithms , 2009, Physics in medicine and biology.

[35]  Dwight E Heron,et al.  A cone beam CT-guided online plan modification technique to correct interfractional anatomic changes for prostate cancer IMRT treatment , 2009, Physics in medicine and biology.

[36]  L. Xing,et al.  Overview of image-guided radiation therapy. , 2006, Medical dosimetry : official journal of the American Association of Medical Dosimetrists.

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

[38]  Jing Wang,et al.  Inverse determination of the penalty parameter in penalized weighted least-squares algorithm for noise reduction of low-dose CBCT. , 2011, Medical physics.

[39]  Uwe Oelfke,et al.  Linac-integrated 4D cone beam CT: first experimental results , 2006, Physics in medicine and biology.

[40]  Jin Sung Kim,et al.  Fast compressed sensing-based CBCT reconstruction using Barzilai-Borwein formulation for application to on-line IGRT. , 2012, Medical physics.

[41]  K. Sheng,et al.  The effect of respiratory motion variability and tumor size on the accuracy of average intensity projection from four-dimensional computed tomography: an investigation based on dynamic MRI. , 2008, Medical physics.

[42]  William Y. Song,et al.  A low-complexity 2-point step size gradient projection method with selective function evaluations for smoothed total variation based CBCT reconstructions , 2014, Physics in medicine and biology.

[43]  P. Munro,et al.  Four-dimensional cone-beam computed tomography using an on-board imager. , 2006, Medical physics.

[44]  Boyd McCurdy,et al.  Cone beam computerized tomography: the effect of calibration of the Hounsfield unit number to electron density on dose calculation accuracy for adaptive radiation therapy , 2009, Physics in medicine and biology.

[45]  Hao Yan,et al.  Towards the clinical implementation of iterative low-dose cone-beam CT reconstruction in image-guided radiation therapy: cone/ring artifact correction and multiple GPU implementation. , 2014, Medical physics.

[46]  Jin Sung Kim,et al.  Four-dimensional cone-beam computed tomography and digital tomosynthesis reconstructions using respiratory signals extracted from transcutaneously inserted metal markers for liver SBRT. , 2011, Medical physics.

[47]  E. Hall,et al.  Lessons we have learned from our children: cancer risks from diagnostic radiology , 2002, Pediatric Radiology.

[48]  David J Brenner,et al.  Estimated radiation risks potentially associated with full-body CT screening. , 2004, Radiology.

[49]  Guang-Hong Chen,et al.  Reduced image noise at low-dose multidetector CT of the abdomen with prior image constrained compressed sensing algorithm. , 2011, Radiology.

[50]  M. Reiser,et al.  Radiation exposures of cancer patients from medical X-rays: how relevant are they for individual patients and population exposure? , 2009, European journal of radiology.

[51]  Steve B. Jiang,et al.  Ultra-Fast Digital Tomosynthesis Reconstruction Using General-Purpose GPU Programming for Image-Guided Radiation Therapy , 2011, Technology in cancer research & treatment.

[52]  Lei Xing,et al.  Enhanced 4D cone-beam CT with inter-phase motion model. , 2007, Medical physics.

[53]  Jan-Jakob Sonke,et al.  Variability of four-dimensional computed tomography patient models. , 2008, International journal of radiation oncology, biology, physics.

[54]  Guang-Hong Chen,et al.  Dual energy CT using slow kVp switching acquisition and prior image constrained compressed sensing , 2010, Physics in medicine and biology.