Characterization of statistical prior image constrained compressed sensing (PICCS): II. Application to dose reduction

Thériault-Lauzier, Pascal; Chen, Guang-Hong

doi:10.1118/1.4773866

Cited by 59 publications

(50 citation statements)

References 43 publications

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“…All of these situations present an excellent opportunity to apply prior-image-based reconstruction (PIBR) methods that leverage high-fidelity prior imaging studies to help improve the image quality or reduce the x-ray exposures in subsequent studies. A myriad of algorithms have been proposed that take advantage of high-fidelity prior images of a patient to reconstruct lower fidelity current measurements including Prior image constrained compressed sensing (PICCS) with statistical weighting [3], or in Prior Image Registration, PenalizedLikelihood Estimation (PIRPLE) [4]. Another class of PIBR methods seeks to reconstruct only the difference between the current anatomy and the prior image.…”

Section: Introductionmentioning

confidence: 99%

A generalized Fourier penalty in prior-image-based reconstruction for cross-platform imaging

2016

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Sequential CT studies present an excellent opportunity to apply prior-image-based reconstruction (PIBR) methods that leverage highfidelity prior imaging studies to improve image quality and/or reduce x-ray exposure in subsequent studies. One major obstacle in using PIBR is that the initial and subsequent studies are often performed on different scanners (e.g. diagnostic CT followed by CBCT for interventional guidance); this results in mismatch in attenuation values due to hardware and software differences. While improved artifact correction techniques can potentially mitigate such differences, the correction is often incomplete. Here, we present an alternate strategy where the PIBR itself is used to mitigate these differences. We define a new penalty for the previously introduced PIBR called Reconstruction of Difference (RoD). RoD differs from many other PIBRs in that it reconstructs only changes in the anatomy (vs. reconstructing the current anatomy). Direct regularization of the difference image in RoD provides an opportunity to selectively penalize spatial frequencies of the difference image (e.g. low frequency differences associated with attenuation offsets and shading artifacts) without interfering with the variations in unchanged background image. We leverage this flexibility and introduce a novel regularization strategy using a generalized Fourier penalty within the RoD framework and develop the modified reconstruction algorithm. We evaluate the performance of the new approach in both simulation studies and in physical CBCT test-bench data. We find that generalized Fourier penalty can be highly effective in reducing low-frequency x-ray artifacts through selective suppression of spatial frequencies in the reconstructed difference image.

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Section: Introductionmentioning

confidence: 99%

A generalized Fourier penalty in prior-image-based reconstruction for cross-platform imaging

2016

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“…Among them, statistical iterative reconstruction (SIR) methods by modeling the measurement statistics and imaging geometry can significantly reduce radiation dose while maintaining image quality in various CT applications compared with the filtered back-projection (FBP) reconstruction algorithm (Elbakri and Fessler, 2002, Tang et al , 2009, Lauzier Thériault and Chen, 2013). Usually, the cost function of SIR consists of two components, i.e., the data-fidelity term and regularization term.…”

Section: Introductionmentioning

confidence: 99%

Sparse-view x-ray CT reconstruction via total generalized variation regularization

et al. 2014

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Sparse-view CT reconstruction algorithms via total variation (TV) optimize the data iteratively on the basis of a noise- and artifact-reducing model, resulting in significant radiation dose reduction while maintaining image quality. However, the piecewise constant assumption of TV minimization often leads to the appearance of noticeable patchy artifacts in reconstructed images. To obviate this drawback, we present a penalized weighted least-squares (PWLS) scheme to retain the image quality by incorporating the new concept of total generalized variation (TGV) regularization. We refer to the proposed scheme as “PWLS-TGV” for simplicity. Specifically, TGV regularization utilizes higher order derivatives of the objective image, and the weighted least-squares term considers data-dependent variance estimation, which fully contribute to improving the image quality with sparse-view projection measurement. Subsequently, an alternating optimization algorithm was adopted to minimize the associative objective function. To evaluate the PWLS-TGV method, both qualitative and quantitative studies were conducted by using digital and physical phantoms. Experimental results show that the present PWLS-TGV method can achieve images with several noticeable gains over the original TV-based method in terms of accuracy and resolution properties.

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“…The compressive sensing concept utilizes the sparseness of the natural signals and images in di erent domains such as time, space, and frequency in order to reconstruct the desired signal with less-than-Nyquist samples [4][5][6]. Specically, the Compressed Sensing (CS) method has found its application in CT imaging, being able to provide a low-radiation CT image reconstruction platform [7][8][9][10][11][12][13]. In fact, by using the CS approach in CT algorithms, the reconstruction process can be done with small number of data, reducing the health risk.…”

Section: Introductionmentioning

confidence: 99%

“…Another group of CS-based CT image reconstruction approaches use Total Variation (TV) for image reconstruction with incomplete set of measurements [9][10][11]. Bian et al exploited the sparsity of objects in the Total Variation (TV) domain, naming it the CSTV model [9].…”

Section: Introductionmentioning

confidence: 99%

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Improved CT Image Reconstruction Through Partial Fourier Sampling

2016

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Abstract. A novel CT imaging structure based on Compressive Sensing (CS) is proposed.The main goal is to mitigate the CT imaging time and, thus, X-ray radiation dosage without compromising the image quality. The utilized compressive sensing approach is based on radial Fourier sampling. Thanks to the intrinsic relation between captured radon samples in a CT imaging process and the radial Fourier samples, partial Fourier sampling could be implemented systematically. This systematic compressive sampling helps in better control of required conditions such as incoherence and sparsity to guarantee adequate image quality in comparison to previous CS-based CT imaging structures. Simulation results prove the superior quality of the proposed approach (about 4% improvement in peak signal-to-noise ratio), achieving the smallest CT scan time and the best image quality.

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Characterization of statistical prior image constrained compressed sensing (PICCS): II. Application to dose reduction

Cited by 59 publications

References 43 publications

A generalized Fourier penalty in prior-image-based reconstruction for cross-platform imaging

A generalized Fourier penalty in prior-image-based reconstruction for cross-platform imaging

Sparse-view x-ray CT reconstruction via total generalized variation regularization

Improved CT Image Reconstruction Through Partial Fourier Sampling

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