SIRF: Synergistic Image Reconstruction Framework

Ovtchinnikov, Evgueni; Atkinson, David; Kolbitsch, Christoph; Thomas, Benjamin A.; Bertolli, Ottavia; Costa-Luis, Casper da; Efthimiou, Nikos; Fowler, R F; Pasca, E.; Wadhwa, Palak; Emond, Elise; Matthews, Julian C.; Prieto, Claudia; Reader, Andrew J.; Tsoumpas, Charalampos; Turner, Martin; Thielemans, Kris

doi:10.1109/nssmic.2017.8532815

Cited by 19 publications

(28 citation statements)

References 3 publications

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“…A practical difficulty with synergistic methods, especially in multi-modality imaging, is the need for software that can handle large amounts of data, is capable to accurately compute the system models (4), and ideally allows easy experimentation with novel algorithms. It is therefore often necessary to combine several software packages, ideally via an overarching framework [132] or by writing interfaces to other packages such that they can be used in an optimisation library such as [133,134,135].…”

Section: Discussion and Outlookmentioning

confidence: 99%

(An overview of) Synergistic reconstruction for multimodality/multichannel imaging methods

Arridge

Ehrhardt

Thielemans

2021

Phil. Trans. R. Soc. A.

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Imaging is omnipresent in modern society with imaging devices based on a zoo of physical principles, probing a specimen across different wavelengths, energies and time. Recent years have seen a change in the imaging landscape with more and more imaging devices combining that which previously was used separately. Motivated by these hardware developments, an ever increasing set of mathematical ideas is appearing regarding how data from different imaging modalities or channels can be synergistically combined in the image reconstruction process, exploiting structural and/or functional correlations between the multiple images. Here we review these developments, give pointers to important challenges and provide an outlook as to how the field may develop in the forthcoming years. This article is part of the theme issue ‘Synergistic tomographic image reconstruction: part 1’.

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Section: Discussion and Outlookmentioning

confidence: 99%

(An overview of) Synergistic reconstruction for multimodality/multichannel imaging methods

Arridge

Ehrhardt

Thielemans

2021

Phil. Trans. R. Soc. A.

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“…PET acquisitions were simulated using Software for Tomographic Image Reconstruction (STIR) [7], [8] through Synergistic Image Reconstruction Framework (SIRF) [9], [10] to forward project the input data to sinograms using the geometry of a GE Discovery 710 and, where relevant, a TOF resolution of 375ps similar to the GE Signa PET/MR (using TOF mashing to reduce computation time resulting in 13 TOF time bins of size 376.5ps). Attenuation was included in the simulation using the relevant mu-map generated by XCAT.…”

Section: B Pet Data Simulationmentioning

confidence: 99%

Impact of Time-of-Flight on Respiratory Motion Modelling using Non-Attenuation-Corrected PET

Whitehead

Emond

Efthimiou

et al. 2019

2019 IEEE Nuclear Science Symposium and Medical Imaging Conference (NSS/MIC)

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Respiratory motion reduces image quality in Positron Emission Tomography (PET). Unless gated Computed Tomography (CT) or Magnetic Resonance (MR) data are available, motion correction relies on registration of the PET data. To avoid mis-registration due to attenuation mismatches, most existing methods rely on pair-wise registration of Non-Attenuation Corrected (NAC) PET volumes. This is a challenging problem due to the low contrast and high noise of these volumes. This paper investigates the possibility of using motion models for respiratory motion correction in PET, and in particular whether incorporating Time-of-Flight (TOF) information increases the accuracy of the motion models derived from the NAC reconstructed images. 4D Extended Cardiac-Torso (XCAT) phantom simulations are used for one bed position with a field of view including the base of the lungs and the diaphragm. A TOF resolution of 375ps is used. NAC images are reconstructed using Orded SubSet Expectation Maximisation (OSEM) and used as input for motion model estimation. Different motion models are compared using the original XCAT input volumes. The results indicate that TOF improves the accuracy of the motion model considerably.

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“…Our first application is to reconstruct Positron Emission Tomography (PET) data using the SPDHG 10 algorithm with the Kullback-Leibler (Poisson) data model and two different regularisers from CCPi-RGL: FGP-TV 8 and TGV. 12 We use STIR-SIRF 5,6 software to model realistic PET system blur and apply Poisson noise to the projection data generated from the thorax phantom (see Fig. 2).…”

Section: Algorithm 4 Alternating Directions Of Multipliers (Admm)mentioning

confidence: 99%

“…3 In this paper, we introduce the CCPi-Regularisation Toolkit (CCPi-RGL) 4 for effective and efficient regularisation of iterative methods for application the reconstruction of large 3D tomographic datasets. We demonstrate how the CCPi-RGL toolkit can be used to reconstruct positron emission tomography (PET) data with the STIR-SIRF package 5,6 and also high-resolution synchrotron tomographic data using MPI-based Savu software. 7 2 CCPi-RGL software contents and methodology…”

Section: Introductionmentioning

confidence: 99%

Versatile regularisation toolkit for iterative image reconstruction with proximal splitting algorithms

Kazantsev

Pasca

Basham

et al. 2019

15th International Meeting on Fully Three-Dimensional Image Reconstruction in Radiology and Nuclear Medicine

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Ill-posed image recovery requires regularisation to ensure stability. The presented open-source regularisation toolkit consists of state-of-the-art variational algorithms which can be embedded in a plug-and-play fashion into the general framework of proximal splitting methods. The packaged regularisers aim to satisfy various prior expectations of the investigated objects, e.g., their structural characteristics, smooth or non-smooth surface morphology. The flexibility of the toolkit helps with the design of more advanced model-based iterative reconstruction methods for different imaging modalities while operating with simpler building blocks. The toolkit is written for CPU and GPU architectures and wrapped for Python/MATLAB. We demonstrate the functionality of the toolkit in application to Positron Emission Tomography (PET) and X-ray synchrotron computed tomography (CT).

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SIRF: Synergistic Image Reconstruction Framework

Cited by 19 publications

References 3 publications

(An overview of) Synergistic reconstruction for multimodality/multichannel imaging methods

(An overview of) Synergistic reconstruction for multimodality/multichannel imaging methods

Impact of Time-of-Flight on Respiratory Motion Modelling using Non-Attenuation-Corrected PET

Versatile regularisation toolkit for iterative image reconstruction with proximal splitting algorithms

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