Your search keyword '"Sibomana M"' showing total 5 results

1. Exact and approximate rebinning algorithms for 3-D PET data

Author

Defrise, Michel, Kinahan, P.E., Townsend, D.W., Michel, C., Sibomana, M., and Newport, D.F.

Subjects

PET imaging -- Methods, Brain, Image processing -- Digital techniques, Business, Electronics, Electronics and electrical industries, Health care industry

Abstract

This paper presents two new rebinning algorithms for the reconstruction of three-dimensional (3-D) positron emission tomography (PET) data. A rebinning algorithm is one that first sorts the 3-D data into an ordinary two-dimensional (2-D) data set containing one sinogram for each transaxial slice to be reconstructed; the 3-D image is then recovered by applying to each slice a 2-D reconstruction method such as filtered-backprojection. This approach allows a significant speedup of 3-D reconstruction, which is particularly useful for applications involving dynamic acquisitions or whole-body imaging. The first new algorithm is obtained by discretizing an exact analytical inversion formula. The second algorithm, called the Fourier rebinning algorithm (FORE), is approximate but allows an efficient implementation based on taking 2-D Fourier transforms of the data. This second algorithm was implemented and applied to data acquired with the new generation of PET systems and also to simulated data for a scanner with an 18 [degrees] axial aperture. The reconstructed images were compared to those obtained with the 3-D reprojection algorithm (3DRP) which is the standard 'exact' 3-D filtered-backprojection method. Results demonstrate that FORE provides a reliable alternative to 3DRP, while at the same time achieving an order of magnitude reduction in processing time. Index Terms - Image reconstruction, medical imaging, positron emission tomography, X-ray transform.

Published

1997

2. A standardized blood sampling scheme in quantitative FDG-PET studies

Author

Bentourkia, M., primary, Bol, A., additional, Ivanoiu, A., additional, Michel, C., additional, Coppens, A., additional, Sibomana, M., additional, Cosnard, G., additional, and De Volder, A.G., additional

Published

1999

3. Bias reduction for low-statistics PET: maximum likelihood reconstruction with a modified Poisson distribution.

Author

Van Slambrouck K, Stute S, Comtat C, Sibomana M, van Velden FH, Boellaard R, and Nuyts J

Subjects

Algorithms, Phantoms, Imaging, Poisson Distribution, Image Processing, Computer-Assisted methods, Positron-Emission Tomography methods

Abstract

Positron emission tomography data are typically reconstructed with maximum likelihood expectation maximization (MLEM). However, MLEM suffers from positive bias due to the non-negativity constraint. This is particularly problematic for tracer kinetic modeling. Two reconstruction methods with bias reduction properties that do not use strict Poisson optimization are presented and compared to each other, to filtered backprojection (FBP), and to MLEM. The first method is an extension of NEGML, where the Poisson distribution is replaced by a Gaussian distribution for low count data points. The transition point between the Gaussian and the Poisson regime is a parameter of the model. The second method is a simplification of ABML. ABML has a lower and upper bound for the reconstructed image whereas AML has the upper bound set to infinity. AML uses a negative lower bound to obtain bias reduction properties. Different choices of the lower bound are studied. The parameter of both algorithms determines the effectiveness of the bias reduction and should be chosen large enough to ensure bias-free images. This means that both algorithms become more similar to least squares algorithms, which turned out to be necessary to obtain bias-free reconstructions. This comes at the cost of increased variance. Nevertheless, NEGML and AML have lower variance than FBP. Furthermore, randoms handling has a large influence on the bias. Reconstruction with smoothed randoms results in lower bias compared to reconstruction with unsmoothed randoms or randoms precorrected data. However, NEGML and AML yield both bias-free images for large values of their parameter.

Published

2015

4. Attenuation correction for the HRRT PET-scanner using transmission scatter correction and total variation regularization.

Author

Keller SH, Svarer C, and Sibomana M

Subjects

Algorithms, Brain diagnostic imaging, Fluorodeoxyglucose F18 analysis, Humans, Neuroimaging, Phantoms, Imaging, Reproducibility of Results, Tomography, X-Ray Computed, Image Processing, Computer-Assisted methods, Positron-Emission Tomography instrumentation, Positron-Emission Tomography methods

Abstract

Unlabelled: In the standard software for the Siemens high-resolution research tomograph (HRRT) positron emission tomography (PET) scanner the most commonly used segmentation in the μ -map reconstruction for human brain scans is maximum a posteriori for transmission (MAP-TR). Bias in the lower cerebellum and pons in HRRT brain images have been reported. The two main sources of the problem with MAP-TR are poor bone/soft tissue segmentation below the brain and overestimation of bone mass in the skull., Method: We developed the new transmission processing with total variation (TXTV) method that introduces scatter correction in the μ-map reconstruction and total variation filtering to the transmission processing., Results: Comparing MAP-TR and the new TXTV with gold standard CT-based attenuation correction, we found that TXTV has less bias as compared to MAP-TR. We also compared images acquired at the HRRT scanner using TXTV to the GE Advance scanner images and found high quantitative correspondence. TXTV has been used to reconstruct more than 4000 HRRT scans at seven different sites with no reports of biases., Conclusion: TXTV-based reconstruction is recommended for human brain scans on the HRRT.

Published

2013

5. Exact rebinning methods for three-dimensional PET.

Author

Liu X, Defrise M, Michel C, Sibomana M, Comtat C, Kinahan P, and Townsend D

Subjects

Algorithms, Brain diagnostic imaging, Humans, Phantoms, Imaging, Image Processing, Computer-Assisted methods, Tomography, Emission-Computed

Abstract

The high computational cost of data processing in volume PET imaging is still hindering the routine application of this successful technique, especially in the case of dynamic studies. This paper describes two new algorithms based on an exact rebinning equation, which can be applied to accelerate the processing of three-dimensional (3-D) PET data. The first algorithm, FOREPROJ, is a fast-forward projection algorithm that allows calculation of the 3-D attenuation correction factors (ACF's) directly from a two-dimensional (2-D) transmission scan, without first reconstructing the attenuation map and then performing a 3-D forward projection. The use of FOREPROJ speeds up the estimation of the 3-D ACF's by more than a factor five. The second algorithm, FOREX, is a rebinning algorithm that is also more than five times faster, compared to the standard reprojection algorithm (3DRP) and does not suffer from the image distortions generated by the even faster approximate Fourier rebinning (FORE) method at large axial apertures. However, FOREX is probably not required by most existing scanners, as the axial apertures are not large enough to show improvements over FORE with clinical data. Both algorithms have been implemented and applied to data simulated for a scanner with a large axial aperture (30 degrees), and also to data acquired with the ECAT HR and the ECAT HR+ scanners. Results demonstrate the excellent accuracy achieved by these algorithms and the important speedup when the sinogram sizes are powers of two.

Published

1999