Figures
Abstract
Today, while many researchers focus on the improvement of the regularization term in IR algorithms, they pay less concern to the improvement of the fidelity term. In this paper, we hypothesize that improving the fidelity term will further improve IR image quality in low-dose scanning, which typically causes more noise. The purpose of this paper is to systematically test and examine the role of high-fidelity system models using raw data in the performance of iterative image reconstruction approach minimizing energy functional. We first isolated the fidelity term and analyzed the importance of using focal spot area modeling, flying focal spot location modeling, and active detector area modeling as opposed to just flying focal spot motion. We then compared images using different permutations of all three factors. Next, we tested the ability of the fidelity terms to retain signals upon application of the regularization term with all three factors. We then compared the differences between images generated by the proposed method and Filtered-Back-Projection. Lastly, we compared images of low-dose in vivo data using Filtered-Back-Projection, Iterative Reconstruction in Image Space, and the proposed method using raw data. The initial comparison of difference maps of images constructed showed that the focal spot area model and the active detector area model also have significant impacts on the quality of images produced. Upon application of the regularization term, images generated using all three factors were able to substantially decrease model mismatch error, artifacts, and noise. When the images generated by the proposed method were tested, conspicuity greatly increased, noise standard deviation decreased by 90% in homogeneous regions, and resolution also greatly improved. In conclusion, the improvement of the fidelity term to model clinical scanners is essential to generating higher quality images in low-dose imaging.
Citation: Do S, Karl WC, Singh S, Kalra M, Brady T, Shin E, et al. (2014) High Fidelity System Modeling for High Quality Image Reconstruction in Clinical CT. PLoS ONE 9(11): e111625. https://doi.org/10.1371/journal.pone.0111625
Editor: Arrate Muñoz-Barrutia, University of Navarra, Spain
Received: June 11, 2014; Accepted: October 3, 2014; Published: November 12, 2014
Copyright: © 2014 Do et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Data Availability: The authors confirm that, for approved reasons, some access restrictions apply to the data underlying the findings. Data are available from the Massachusetts General Hospital Institutional Data Access/Ethics Committee for researchers who meet the criteria for access to confidential data. Please contact the corresponding author ‘Synho Do, PhD’ sdo@mgh.harvard.edu.
Funding: The authors have no funding or support to report.
Competing interests: The authors have declared that no competing interests exist.
Introduction
Computed tomography (CT) is one of the most commonly used diagnostic imaging modalities in modern medicine. CT enables rapid, non-invasive image acquisition at high resolutions. However, CT also exposes the patient to radiation [1], [2]. CT dosage can be decreased by lowering either the voltage or the flux. Lowering the voltage implies that the emitted photons are less energetic, reducing their ability to penetrate through the body. Lowering the flux reduces the number of photons emitted, further degrading the signal-to-noise ratio of the acquired data. Therefore, the consequence of low-dose CT imaging is that the resulting images are considerably noisier than images acquired with todays clinical doses [3].
The drive towards lower dose CT imaging (while maintaining the diagnostic quality of CT) has been an area of focus for the entire CT community [4]–[9]. Numerous approaches to dose reduction have been implemented in commercial systems including the use of filters [10]–[12], collimators [13], dose modulation [14], [15], prospective triggering [6], patient-specific protocols [16], [17], and more [12], [18]. One additional component to the current repertoire of low-dose CT scanning techniques is the use of new image reconstruction techniques.
Through recent studies, iterative reconstruction (IR) algorithms have been shown to be more robust than FBP algorithms in regards to the presence of noise and artifacts [8], [19]–[25]. Numerous researchers have discussed different aspects of formulations [26]–[31] and optimization approaches [32]–[36]. However, we have found that having a high fidelity model of the imaging system is also a critical factor in the reconstruction of high quality images; this is an aspect of iterative reconstruction algorithms which has often been either neglected or substantially simplified [37], [38].
A critical component of tomographic IR algorithms is the accuracy of the forward system model. In positron emission tomography (PET), the forward system model consists of a geometric projection matrix and a sinogram blurring matrix, which can be either measured or simulated [39], [40]. It is shown that the combined model improves resolution and contrast-to-noise ratio in PET imaging [41]. It is also possible to reuse the stored system matrix to improve computation time because the PET scanner is stationary, making it relatively easy to factorize the system model based on symmetric geometry. A similar method is applied to single photon emission computed tomography (SPECT) for the estimation of the depth-dependent component of the point spread function (PSF) [42]. However, it is a challenging task to derive an explicit system matrix in clinical CT for the following reasons: i) each scan has a different scan length and pitch based on the scanning protocol, and ii) it is very hard to find symmetries in cone beam helical CT scans because the source-detector set has a functional misalignment (i.e., a quarter of a detector offset [43]) and view-by-view deflections of the X-ray source spot (i.e., flying focal spot (FFS) [44]).
In this paper, we show the systematic implementation of accurate system modeling for an IRT in clinical CT. A similar approach for PET [45] was derived from an analytical formula for calculating error propagation in a reconstructed image from the system matrix. In addition, in the cone-beam CT, the beam divergence and the rotation of the X-ray source and detector unit give space-variant effect on image. Since we do not use a system matrix as in PET, we integrate all the functional misalignment and fabrication limitations with on-the-fly calculation method so that the space-invariant nature is embedded in the forward model. Therefore, when we run image reconstruction algorithm, we set up on/off parameters for each modular model. That is one of major differences of our results compared to the previous 2D or phantom simulation works.
Also, there are algorithms (ASIR, IRIS, iDose, VEO, etc.) implemented in clinical scanners by vendors, but the technical description and detailed methods are not available to the research community. In this paper, we systematically demonstrate the necessity of implementing focal spot area, flying focal spot, and detector area in the forward system model to generate higher quality images. We also compare our raw-data-domain IRT with a mathematical formulation of image domain iteration called Iterative Reconstruction in Image Space (IRIS). The purpose of this paper is to examine the role of high-fidelity system models in the performance of the iterative image reconstruction approach minimizing energy functional. This paper is organized as follows. In section 2, we mathematically describe iterative image reconstruction and the components of proposed system models. In section 3, we present some initial results on phantom and in vivo data. In section 4, we summarize our findings and conclusions.
Methods
In this section, we describe the mathematical formulation of IRT and a detailed forward system modeling method. The forward system modeling method can be decomposed into a series of components to increase modeling accuracy. We structure a three-component model that incorporates the most important elements of the system model. Each component can be replaced by a specific scanner parameter or vendor-specific model. The accuracy of this system model is critical in the improvement of image quality of a reconstructed image.
On-the-fly System Modeling and Reconstruction Formulation for Clinical Scanner
We assume a transmission CT system with a field of x-ray attenuation coefficients and projection operator
as modeled by:
(1)where
denotes the projection sinogram, and
denotes noise. We formulate our reconstruction problem by the following equation:
(2)where
is the data fidelity term between image
and sinogram
via the projection process. The second term
is the prior, or regularization term, and
is the weighting term. We formulate the fidelity term as:
(3)where
is the system matrix, or projection process. One example of the regularization term
is the
norm:
(4)
When and
,
becomes a Total Variation (TV) regularizer, which is commonly used to suppress noise and preserve edges in the image [46], [47]. From a modeling perspective, we make the assumption that
, the system matrix, can be decomposed into a series of component models:
(5)
The models include a geometric projector (), a focal spot model (
), and an active detector response function (
). By decomposing a system matrix
into sub-components, the implementation of complex clinical scanner modeling becomes more feasible. This approach also increases the usability of a single developed code across multiple CT systems, as opposed to requiring entirely different projectors for each system.
In this paper, we used the least-squares (LS) solution without the regularization term and TV solution in Equation (2) and (4) for comparison. The lagged diffusivity fixed-point method [46], [48], where we iteratively approximated the cost by a weighted quadratic cost and then solved the resulting linear normal equations using pre-conditioned conjugated gradient (CG) iterations, is used to minimize the energy functional in Equation (2) [49].
Focal Spot Area Modeling
A focal spot is the region where electrons transfer their energy to target atoms in order to generate X-rays. In many cases, the focal spot is approximated as a point model, but in reality, the focal spot consists of a finite area (i.e., 0.3 to 0.8
) [50]. Furthermore, the size of this area changes with scanner settings (
or
), an important consideration in regards to image reconstruction of low dose scans. Figure 1 illustrates the focal spot area with the length (
), width (
), and height (
) of the area in the diagram. This sub-module should be included for accurate forward system modeling.
Flying Focal Spot (FFS) Modeling
The detector elements form an equiangular concentric cylindrical structure with rows and
channels (i.e., 1st generation Dual Source CT, Siemens, Definition) with FFS models as shown in Figure 2. We assume the active area of all detector elements (i.e.,
) is identical for all elements according to manufacturer specifications. In Siddon-type ray-based projectors, a single ray sum is calculated for a single detector element by using the ratio of intersections of the ray with equally spaced parallel lines [51]. For our IR technique, we calculate a bundle of rays to simulate the virtual ray, which shapes the volume from the focal spot area to the active detector area. The ratio of the active detector area to physical spacing between detector elements was provided to us by the scanner manufacturer as 85% in the angular direction and 80% in the z-direction as shown in Figure 3. These ratios can be changed for different systems.
The Siddon projector calculates only the weighted sums of the portion of the ray that intersects through each voxel without considering and compensating for the neighboring voxels, generating aliasing artifacts [52]. Multiple rays in the volume beam can be used to compensate for this aliasing effect at the expense of over-sampling the image grid [53]. We have additionally implemented a version of the Siddon projector which does not require recursion [54], thus making it amendable to parallel implementations [55].
Figure 3-(b) shows how we divide active sub-elements to compute ray-sums. In Figure 3-(b), a single element model, as well as a multiple element model that strictly limits the active area of the detector (i.e., middle sub-figure), is depicted. We have noticed, however, that applications with reconstructions on voxel sizes that are finer than the detector size itself requires a greater over-sampling of the detector. In this case, not only does the computational demand increase, but the gap between the active areas of two adjacent detectors begin to introduce artifacts. As such, we have implemented the active area model depicted in the right sub-figure of Figure 3-(b), where the rays intersect the major boundary points, leading to a higher quality reconstruction.
Results
We show two experimental results in this section. For the phantom study, we focus on the comparison between the effects of each model on the LS images with a cone beam phantom (QRM, Moehrendorf, Germany) with respect to conspicuity improvement, noise statistics, and resolution. In an in vivo study, we show clinical evidence that supports the proposed approach with subjective assessment. The proposed method is compared with conventional FBP and image domain IR (IRIS) algorithms in a low dose scan. In this case, we used the same raw data for image reconstructions.
Phantom Study
A cone beam phantom with a spatial resolution section with circularly aligned line-patterns varying from
to
was scanned on a dual source
-slice multi-detector row CT (Definition, Siemens Healthcare, Forchheim, Germany) using the following parameters: detector collimation =
, table speed
per gantry rotation, gantry rotation
, tube current
, and tube voltage
.
In the following sections we demonstrate the impact of our various system modules. We will use the following notation: the triplet to denote with a
or
, whether the focal spot model, flying focal spot model, and detector model, respectively, are turned on (
) or off (
). Thus, for example,
indicates that the flying focal spot model is turned on, while the other two system models are turned off.
Figure 4 shows the LS solutions reconstructed using all permutations of . Additionally, the differences between these permutations and the case in which all models are turned on (
) are shown. All reconstructed images are shown with a windowing level of
, and difference images are shown with the full dynamic range of each difference so that patterns of artifacts are visible. The model without FFS generates the stellar shape artifact from the center of the rotation and it causes major deterioration of image quality. Therefore, FFS modeling is one of the most important components of clinical system modeling. The image quality evaluations in analytic reconstruction methods are shown in papers [44], [56]. In analytic reconstruction methods, the locations of X-ray source and detector elements are the only models that can be implemented in the algorithm, so it is easy to overlook the importance of FS and DM.
:
: Focal Spot model,
: Flying Focal Spot model, and
: Detector model.
In Figure 4, we can visually compare image qualities of Siddon-type model with FFS and the proposed method
including focal spot and detector models to acquire a more accurate system model and to remove Moire patterns. There are only small differences between the two models, especially around the edges of the image, but eventually these will cause a significant change in the final image (i.e., TV regularization), especially in low dose scans. To suppress noise in low dose imaging, we frequently use regularization terms in Equation (2) with which we suppress noise by keeping the structure components of the image. When there are small model discrepancies related to the fidelity term in Equation (3), the mismatches can be concealed by noise and may cause resolution degradation and eventually poor contrast.
To compare artifact propagation, we compare the LS and TV images with a soft contrast section of the phantom. The three cross-sections of the soft contrast region are displayed in Figure 5-(a). Figure 5-(b), (c), and (d) show the axial views of line A, B, and C respectively. The top images are from Siddon-type model with and the bottom images are from the proposed method
. By the number of iteration (i.e., LS:
and
iteration, TV:
iteration), we can observe circular line artifacts on LS and TV, as well as on the Siddon-type model. It is especially more obvious in a very low contrast case (Figure 5-(b)). However, the images reconstructed by the proposed method show high quality images without any artifacts in both LS and TV. As expected, the TV images show significant noise suppression.
The FFS only model (so called Siddon Model, ) shows circular line artifacts in LS and TV as well. In contrast, the proposed model (
) shows high quality image even in LS without regularization term and significant noise suppression effect on TV.
To observe the effects of iterations, we simulated a Siddon-type projector with proper model
without
and
, and a complete model
including all modular models in Section 2. Both methods used the same optimization algorithm and code (C++ and Open MPI) to reconstruct images and consecutively calculate the NRMSE (Normalized Root Mean Square Error):
(6)where
is the
iteration result of LS-solution with
elements.
Figure 6 compares the consecutive errors with iteration for Siddon and the proposed method
in the log-log scale. The Siddon-type projector shows similar updates to the proposed method until iteration-
, where it plateaus and then fluctuates. The resulting image from the Siddon projector does not provide the best image even though it reaches the solution of Equation (3). In contrast, the NRMSEs for our proposed method become smaller even after 15-iterations because the modeling error decreases with increasing iterations. However, the high frequency and noise components of the
iterations become dominant in the system modeling.
The NRMSEs of two consecutive images are calculated and displayed in log-log plot. The proposed method exhibits smaller consecutive errors after iterations compared to Siddon method and reaches smaller modeling error.
Note that the proposed method exhibits significant modeling error reduction in terms of visual evaluation and NRMSE taking into account the nonlinear scaling of log-log plot.
Conspicuity Improvements.
In Figure 7, we display a contrast resolution section of QRM phantoms scanned in the clinical system. We show four groups of circles with different attenuation coefficients in Hounsfield Units (HU) (, and
HU) in tissue equivalent background (
HU) at
. Each group consists of
circular inserts with different diameters (
, and
). We used the same raw data for the comparison of four different reconstruction methods: Figure 7-(a) FBP with sharp kernel filtering, (b) FBP with soft kernel filtering, (c) Least-Squares (LS) solution after 30-iterations, and (d) Total Variation (TV) image after 10-iterations with (c) initialization.
We found that it is difficult to detect low contrast circles (for example, circles in
and
HU groups) visually as shown in Figure 7-(a), (b), and (c). Notice that there is no improvement of conspicuity in small circles with low contrast even with the smoothing kernel, Figure 7-(b). Basically, it suppresses high frequency noise components on the image without keeping small and low contrast information, which is key to the evaluation of low contrast tissues and lesions in most soft tissues such as the brain, liver, spleen, and lymph nodes, given subtle or low differences in HU values between organs and several of these legions (i.e., neoplasms and infarcts).
However, we can easily identify circles in
and
HU groups from Figure 7-(d). The TV image can be initialized on FBP image and can replace the LS solution.
Noise Statistics.
Figure 8 compares noise patches from five noise regions for each image in Figure 7: one from each tissue equivalent region at the center of the Phantom and four circles from different HU groups (
, and
HU). Each sampled region is concatenated with dividing columns (zeros) and displayed in a dynamic contrast window to show noticeable differences. The FBP with sharp kernel filtering and LS solutions show similar noise patterns. As shown in Table 1, a smoother and lower spatial frequency kernel FBP with soft kernel filtering has lower noise compared to that of a sharper and higher spatial frequency kernel FBP (sharp kernel). However, TV shows a strong noise suppression capability and retains visibility of small and low-contrast circular objects that are, in our opinion, from accurate system modeling.
Each sampled region is concatenated with dividing columns (zeros) and displayed in dynamic contrast window to show noticeable differences. From left to right, FBP with sharp kernel filtering, FBP with soft kernel filtering, IRT (LS), and IRT (TV).
The image reconstruction formulation in Equation (2) emphasizes that the energy functional aggregates a fidelity term and a regularization term. When the system model is not accurate enough to model details of the system, the TV-regularization (Equation (4)) of the energy functional (Equation (2)) smears or even loses the signal components associated with lower HU rather than noise when enforcing the smoothness constraint (i.e., -norm) as in Equation (4). This can even occur to greater signal components in low dose CT data, when the system model is inaccurate and iteration proceeds to suppress amplified noise.
On the other hand, the accurate system model sustains small signal components in the fidelity term so that it eventually reveals hidden signal components under the noise components.
Resolution.
The reconstruction parameters of FBP and the proposed IRT method are set to be the same as slice-thickness
.
The spatial resolution bar patterns are displayed in Figure 9 with a contrast window. FBP (sharp kernel) and FBP (soft kernel) had similar resolutions, so only the better FBP (sharp kernel) is displayed in Figure 9-(a) and compared to the TV with advanced model in Figure 9-(b). Note that the arrows in Figure 9-(b) indicate
and
inserts, which points to clear improvement of spatial resolution on the TV with advanced modeling image.
(a) shows clear separations of 4, 6, and 8 and (b) presents improved resolution showing 10 and 12
bar patterns. (c) compares profiles of spatial resolution inserts.
In vivo study
In the in vivo study, we only show clinical evidences of the proposed approach with subjective assessment. The proposed method is compared with conventional FBP and image domain IR algorithm (IRIS) in a low dose scan. In this case, we used the same raw data for image reconstructions. This study was conducted in compliance with the Health Insurance Portability and Accountability Act (HIPAA) and used a scan protocol approved by the Massachusetts General Hospital Institutional Review Board (IRB). We obtained written informed consent as per Federal U.S. guidelines. All procedures in this study were performed in accordance with the approved protocol.
A patient was scanned on a dual source -slice MDCT (1st generation DSCT Definition, Siemens Medical Solutions) using routine abdominal CT protocols. The scan parameters were
,
, and
second gantry rotation. The reconstructed images show low dose image quality by reconstructing images with only half the data (i.e., detector A).
For this case, images with the volume were reconstructed. For FBP, the sharp kernel on the scanner was utilized. For Iterative Reconstruction in Image Space (IRIS) [57], [58], the corresponding sharp kernel was chosen. IRIS is developed on a novel mathematical algorithm through iterative formation. The image domain iteration is initiated after it reconstructs a master volume, which is reconstructed based on how the scan projections provide image detail information, while reducing noise and enhancing object contrast step by step. IRIS utilizes well-established convolution kernels so that it is very fast compared to raw data domain iterative reconstruction.
In this experiment, we compare three different reconstruction approaches: the conventional FBP method, image domain iterative IRIS, and raw data domain IRT with the proposed methods. We have used -iterations with
for IRT reconstruction with the proposed system modeling method.
To compare images, we defined a priori the regions of comparison. For SNR, the signal is defined over the region containing the hepatic artery, while the background standard deviation is chosen from patches (over slices) of the liver without vasculature. We define CNR as:
(7)where
and
are mean signal intensities of signal producing structures of the liver (
) and the mean signal of the camper's fascia (
), respectively. To obtain CNR background statistics, the standard deviation of the camper's fascia over
slices was computed, and is denoted by
by in Equation (7).
A comparison of reconstruction algorithms for the half-dose scan is shown in Figure 10. Although the added noise associated with this low-dose scan is apparent, no undesired texturing appears in this set of images either. The proposed method shows better visual impression compared to FBP and IRIS.
We also tabulate the SNR and CNR of the low-dose scans, in Table 2 and 3, respectively. The proposed method preserves the signal/contrast at much reduced noise for the low-dose acquisition. In this paper, we choose the regularization parameter based on clinician's feedback so it can be improved by processing more cases with broad feedback from multiple radiologists.
In this study, we showed the efficacy and impact of the proposed method in the real clinical scanner.
Discussions and Conclusions
Modern CT systems are highly complex, and different reconstruction algorithms go to various lengths to model such complexities. In this paper, we show that the accurate modeling of system components such as focal spot area, flying focal spot, and active detector area can make a significant difference in the quality of reconstructed images.
Our phantom and patient studies show that the proposed technique can improve image quality (low contrast, noise statistics, spatial resolution, and visual impression). We have introduced a modular system modeling framework for a sophisticated clinical CT scanner. Even within the same system, some functions can be turned off or manipulated for clinical purposes. The advanced functions of state-of-art CT scanners need to be modeled accordingly for high quality image reconstruction. These parameter changes are meticulously recorded in the header files of raw data. None of these functions can be ignored for accurate system modeling to develop high-fidelity characteristics of an iterative algorithm.
As shown in Figure 4, there are sub-modules of the system that cause a small mismatch in system modeling, but these can be propagated through iterations, making them very hard to correct or compensate for by post-processing or utilization of regularization terms. Many studies claim that they can produce high quality SNR images with simple phantoms (having a few high density structures with homogeneous background) in low dose imaging; however, it is very hard to contain the small low-contrast structure in the final results without advanced system modeling. Without satisfying the fidelity term of the energy functional in Equation (3), we cannot guarantee that the reconstructed image is “the only stable solution” of this ill-posed image reconstruction problem.
At 50% dose, both IRIS and the proposed TV with advanced system modeling were found to be diagnostically acceptable. Although the proposed TV provided objectively superior images in terms of SNR and CNR, this image quality was achieved through a significant amount of processing. As a technique that achieves fast computations while maintaining good image quality, a hybrid method (such as IRIS) may potentially be a promising approach.
Future work will also address a variety of dose reductions on cadavers, and we anticipate being able to reduce computation time for the proposed advanced system modeling by implementing it on parallel computing architectures.
Acknowledgments
The authors gratefully acknowledge Dr. Herbert Bruder, Dr. Karl Stierstofer, Christianne Leidecker, and Dr. Thomas G. Flohr (Siemens Healthcare) for providing system geometry and data structure information of CT sinogram.
Author Contributions
Conceived and designed the experiments: SD WCK TB HP. Performed the experiments: SS MK TB HP. Analyzed the data: SD WCK HP. Contributed reagents/materials/analysis tools: SD. Wrote the paper: SD ES HP.
References
- 1. Brenner DJ, Elliston CD, Hall EJ, Berdon WE (2001) Estimated risks of radiation-induced fatal cancer from pediatric CT. American Journal of Roentgenology 176: 289–296.
- 2. Brenner DJ, Hricak H (2010) Radiation Exposure From Medical Imaging. JAMA: The Journal of the American Medical Association 304: 208.
- 3. Kalra MK, Maher MM, Sahani DV, Blake MA, Hahn PF, et al. (2003) Low-Dose CT of the Abdomen: Evaluation of Image Improvement with Use of Noise Reduction Filters-Pilot Study1. Radiology 228: 251–256.
- 4. Pontana F, Duhamel A, Pagniez J, Flohr T, Faivre J-B, et al. (2011) Chest computed tomography using iterative reconstruction vs filtered back projection (Part 2): image quality of low-dose CT examinations in 80 patients. European radiology 21: 636–643.
- 5. Scheffel H, Alkadhi H, Leschka S, Plass A, Desbiolles L, et al. (2008) Low-dose CT coronary angiography in the step-and-shoot mode: diagnostic performance. Heart 94: 1132–1137.
- 6. Husmann L, Valenta I, Gaemperli O, Adda O, Treyer V, et al. (2007) Feasibility of low-dose coronary CT angiography: first experience with prospective ECG-gating. European heart journal
- 7. Marin D, Nelson RC, Schindera ST, Richard S, Youngblood RS, et al. (2009) Low-Tube-Voltage, High-Tube-Current Multidetector Abdominal CT: Improved Image Quality and Decreased Radiation Dose with Adaptive Statistical Iterative Reconstruction Algorithm-Initial Clinical Experience 1. Radiology 254: 145–153.
- 8. Prakash P, Kalra MK, Kambadakone AK, Pien H, Hsieh J, et al. (2010) Reducing abdominal CT radiation dose with adaptive statistical iterative reconstruction technique. Investigative radiology 45: 202–210.
- 9. Fazel R, Krumholz HM, Wang Y, Ross JS, Chen J, et al. (2009) Exposure to low-dose ionizing radiation from medical imaging procedures. New England Journal of Medicine 361: 849–857.
- 10. Kan MW, Leung LH, Wong W, Lam N (2008) Radiation dose from cone beam computed tomography for image-guided radiation therapy. International Journal of Radiation Oncology* Biology* Physics 70: 272–279.
- 11. Kwan AL, Boone JM, Shah N (2005) Evaluation of x-ray scatter properties in a dedicated cone-beam breast CT scanner. Medical physics 32: 2967–2975.
- 12. Kalra MK, Maher MM, Toth TL, Hamberg LM, Blake MA, et al. (2004) Strategies for CT Radiation Dose Optimization 1. Radiology 230: 619–628.
- 13.
Hsieh J (2009) Computed tomography: principles, design, artifacts, and recent advances. SPIE Bellingham, WA.
- 14. Hentschel D, Popescu S, Strauss K-E, Wolf H (1999) Adaptive dose modulation during CT scanning. Google Patents
- 15. Kalra MK, Maher MM, D′Souza RV, Rizzo S, Halpern EF, et al. (2005) Detection of Urinary Tract Stones at Low-Radiation-Dose CT with Z-Axis Automatic Tube Current Modulation: Phantom and Clinical Studies 1. Radiology 235: 523–529.
- 16. McCollough CH, Bruesewitz MR, Kofler Jr JM (2006) CT Dose Reduction and Dose Management Tools: Overview of Available Options 1. Radiographics 26: 503–512.
- 17. Singh S, Kalra MK, Moore MA, Shailam R, Liu B, et al. (2009) Dose Reduction and Compliance with Pediatric CT Protocols Adapted to Patient Size, Clinical Indication, and Number of Prior Studies 1. Radiology 252: 200–208.
- 18. Li J, Udayasankar UK, Toth TL, Seamans J, Small WC, et al. (2007) Automatic patient centering for MDCT: effect on radiation dose. American Journal of Roentgenology 188: 547–552.
- 19. Shepp LA, Vardi Y (1982) Maximum likelihood reconstruction for emission tomography. Medical Imaging, IEEE Transactions on 1: 113–122.
- 20. Wang G, Snyder DL, O′Sullivan J, Vannier M (1996) Iterative deblurring for CT metal artifact reduction. Medical Imaging, IEEE Transactions on 15: 657–664.
- 21. Thibault J-B, Sauer KD, Bouman CA, Hsieh J (2007) A three-dimensional statistical approach to improved image quality for multislice helical CT. Medical physics 34: 4526.
- 22. Bittencourt MS, Schmidt B, Seltmann M, Muschiol G, Ropers D, et al. (2011) Iterative reconstruction in image space (IRIS) in cardiac computed tomography: initial experience. The international journal of cardiovascular imaging 27: 1081–1087.
- 23. Tang J, Nett BE, Chen G-H (2009) Performance comparison between total variation (TV)-based compressed sensing and statistical iterative reconstruction algorithms. Physics in medicine and biology 54: 5781.
- 24. Sidky EY, Pan X, Reiser IS, Nishikawa RM, Moore RH, et al. (2009) Enhanced imaging of microcalcifications in digital breast tomosynthesis through improved image-reconstruction algorithms. Medical physics 36: 4920.
- 25. Park JC, Song B, Kim JS, Park SH, Kim HK, et al. (2012) Fast compressed sensing-based CBCT reconstruction using Barzilai-Borwein formulation for application to on-line IGRT. Medical Physics 39: 1207.
- 26. Andersen A, Kak A (1984) Simultaneous algebraic reconstruction technique (SART): a superior implementation of the ART algorithm. Ultrasonic imaging 6: 81–94.
- 27. Levitan E, Herman GT (1987) A maximum a posteriori probability expectation maximization algorithm for image reconstruction in emission tomography. Medical Imaging, IEEE Transactions on 6: 185–192.
- 28. Fessler JA (1994) Penalized weighted least-squares image reconstruction for positron emission tomography. Medical Imaging, IEEE Transactions on 13: 290–300.
- 29. Browne JA, Boone JM, Holmes TJ (1995) Maximum-likelihood x-ray computed-tomography finite-beamwidth considerations. Applied optics 34: 5199–5209.
- 30. Fu L, Wang J, Rui X, Thibault J-B, De Man B (2013) Modeling and estimation of detector response and focal spot profile for high-resolution iterative CT reconstruction. Nuclear Science Symposium and Medical Imaging Conference (NSS/MIC), 2013 IEEE. IEEE pp 1–5.
- 31. Little K, La Riviere P (2012) An algorithm for modeling non-linear system effects in iterative CT reconstruction. Nuclear Science Symposium and Medical Imaging Conference (NSS/MIC), 2012 IEEE. IEEE pp 2174–2177.
- 32. Sauer K, Bouman C (1993) A local update strategy for iterative reconstruction from projections. Signal Processing, IEEE Transactions on 41: 534–548.
- 33. De Man B, Nuyts J, Dupont P, Marchal G, Suetens P (2001) An iterative maximum-likelihood polychromatic algorithm for CT. Medical Imaging, IEEE Transactions on 20: 999–1008.
- 34. Hudson HM, Larkin RS (1994) Accelerated image reconstruction using ordered subsets of projection data. Medical Imaging, IEEE Transactions on 13: 601–609.
- 35. Wang G, Snyder DL, O′Sullivan JA, Vannier M (1996) Iterative deblurring for CT metal artifact reduction. Medical Imaging, IEEE Transactions on 15: 657–664.
- 36.
Ramani S, Fessler J (2010) A splitting-based iterative algorithm for accelerated statistical X-ray CT reconstruction. Medical Imaging, IEEE Transactions on: 1–1.
- 37. Do S, Cho S, Karl WC, Kalra MK, Brady TJ, et al. (2009) Accurate model-based high resolution cardiac image reconstruction in dual source CT. IEEE pp 330–333.
- 38. Hofmann C, Knaup M, Kachelrie M (2014) Effects of ray profile modeling on resolution recovery in clinical CT. Medical physics 41: 021907.
- 39. Alessio AM, Kinahan PE, Lewellen TK (2006) Modeling and incorporation of system response functions in 3-D whole body PET. Medical Imaging, IEEE Transactions on 25: 828–837.
- 40. Panin VY, Kehren F, Michel C, Casey M (2006) Fully 3-D PET reconstruction with system matrix derived from point source measurements. Medical Imaging, IEEE Transactions on 25: 907–921.
- 41. Tohme MS, Qi J (2009) Iterative image reconstruction for positron emission tomography based on a detector response function estimated from point source measurements. Physics in Medicine and Biology 54: 3709.
- 42. Beekman FJ, Slijpen ETP, de Jong HWAM, Viergever MA (1999) Estimation of the depth-dependent component of the point spread function of SPECT. Medical physics 26: 2311.
- 43. La Riviere PJ, Pan X (2004) Sampling and aliasing consequences of quarter-detector offset use in helical CT. Medical Imaging, IEEE Transactions on 23: 738–749.
- 44. Kachelrie M, Knaup M, Penel C, Kalender WA (2006) Flying focal spot (FFS) in cone-beam CT. Nuclear Science, IEEE Transactions on 53: 1238–1247.
- 45. Qi J, Huesman RH (2005) Effect of errors in the system matrix on maximum a posteriori image reconstruction. Physics in Medicine and Biology 50: 3297.
- 46. Vogel CR, Oman ME (1996) Iterative methods for total variation denoising. SIAM Journal on Scientific Computing 17: 227–238.
- 47. Sidky EY, Pan X (2008) Image reconstruction in circular cone-beam computed tomography by constrained, total-variation minimization. Physics in Medicine and Biology 53: 4777.
- 48. Chan TF, Mulet P (1999) On the convergence of the lagged diffusivity fixed point method in total variation image restoration. SIAM Journal on Numerical Analysis 354–367.
- 49. Do S, Karl WC, Liang Z, Kalra M, Brady TJ, et al. (2011) A decomposition-based CT reconstruction formulation for reducing blooming artifacts. Physics in Medicine and Biology 56: 7109.
- 50. Hsieh J (2003) Computed tomography: principles, design, artifacts, and recent advances. Society of Photo Optical
- 51. Siddon RL (1985) Fast calculation of the exact radiological path for a three-dimensional CT array. Medical Physics 12: 252.
- 52. Siddon RL (1985) Fast calculation of the exact radiological path for a three?dimensional CT array. Medical physics 12: 252–255.
- 53.
Sunnegardh J, Danielsson PE (2007) A new anti-aliased projection operator for iterative CT reconstruction. pp. 124–127.
- 54. Jacobs F, Sundermann E, De Sutter B, Christiaens M, Lemahieu I (1998) A fast algorithm to calculate the exact radiological path through a pixel or voxel space. Journal of computing and information technology 6: 89–94.
- 55. Jang B, Do S, Pien H, Kaeli D (2009) Architecture-aware optimization targeting multithreaded stream computing. ACM pp 62–70.
- 56. Flohr T, Stierstorfer K, Ulzheimer S, Bruder H, Primak A, et al. (2005) Image reconstruction and image quality evaluation for a 64-slice CT scanner with z-flying focal spot. Medical physics 32: 2536.
- 57.
Tipnis S, Ramachandra A, Huda W, Hardie A, Schoepf J, et al.. Iterative reconstruction in image space (IRIS) and lesion detection in abdominal CT. pp. 76222K.
- 58. Bittencourt MS, Schmidt B, Seltmann M, Muschiol G, Ropers D, et al. (2010) Iterative reconstruction in image space (IRIS) in cardiac computed tomography: initial experience. The International Journal of Cardiovascular Imaging (formerly Cardiac Imaging) 1–7.