Statistical evaluation of PET motion correction methods using MR derived motion fields

Polycarpou, Irene; Tsoumpas, Charalampos; Marsden, Paul

doi:10.1109/nssmic.2011.6153672

Cited by 6 publications

(8 citation statements)

References 30 publications

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“…This result is consistent with previous findings that the MCIR method amplifies noise compared to the non-MoCo. [27][28][29][30][31] However, no significant difference was found between the three PET reconstructions (non-MoCo, MoCo 2000, and MoCo P2P200 ) in Dunn's post hoc pairwise comparison, perhaps due to the small sample size. Despite the higher noise levels, both MoCo 2000 and MoCo P2P200 PET images provided significantly superior lesion conspicuity.…”

Section: Discussionmentioning

confidence: 99%

“…Compared to MoCo 2000 , MoCo P2P200 has larger variations in TBR and CNR in the 5.75 mm at >90 min and 4.75 mm sphere at >70 min. This may be explained by the small size of this spheres, the low activity (<0.062 mCi at >90 min or < 0.071 mCi at >70 min) due to tracer activity decay, and the amplified noise introduced by a short MR scan duration (17 s) and MCIR PET MoCo [27][28][29][30][31]. Of note, the nominal spatial resolution of FDG PET isF I G U R E 8 Representative liver cancer patient 2.…”

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confidence: 99%

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MR‐assisted PET respiratory motion correction using deep‐learning based short‐scan motion fields

Chen

Fraum

Eldeniz

et al. 2022

Magnetic Resonance in Med

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We evaluated the impact of PET respiratory motion correction (MoCo) in a phantom and patients. Moreover, we proposed and examined a PET MoCo approach using motion vector fields (MVFs) from a deep-learning reconstructed short MRI scan. Methods:The evaluation of PET MoCo was performed in a respiratory motion phantom study with varying lesion sizes and tumor to background ratios (TBRs) using a static scan as the ground truth. MRI-based MVFs were derived from either 2000 spokes (MoCo 2000 , 5-6 min acquisition time) using a Fourier transform reconstruction or 200 spokes (MoCo P2P200 , 30-40 s acquisition time) using a deep-learning Phase2Phase (P2P) reconstruction and then incorporated into PET MoCo reconstruction. For six patients with hepatic lesions, the performance of PET MoCo was evaluated using quantitative metrics (SUV max , SUV peak , SUV mean , lesion volume) and a blinded radiological review on lesion conspicuity.Results: MRI-assisted PET MoCo methods provided similar results to static scans across most lesions with varying TBRs in the phantom. Both MoCo 2000 and MoCo P2P200 PET images had significantly higher SUV max , SUV peak , SUV mean and significantly lower lesion volume than non-motion-corrected (non-MoCo) PET images. There was no statistical difference between MoCo 2000 and MoCo P2P200 PET images for SUV max , SUV peak , SUV mean or lesion volume. Both radiological reviewers found that MoCo 2000 and MoCo P2P200 PET significantly improved lesion conspicuity. Conclusion: An MRI-assisted PET MoCo method was evaluated using the ground truth in a phantom study. In patients with hepatic lesions, PET MoCo images improved quantitative and qualitative metrics based on only 30-40 s of MRI motion modeling data.

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Section: Discussionmentioning

confidence: 99%

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confidence: 99%

MR‐assisted PET respiratory motion correction using deep‐learning based short‐scan motion fields

Chen

Fraum

Eldeniz

et al. 2022

Magnetic Resonance in Med

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“…It has been shown by Polycarpou et al (2011) that under some circumstances MCIR may provide superior PET motion correction than RTA, but comes at greater computational cost. Our technique can also be used to provide motion estimates for MCIR-based reconstructions, and in future work we plan to investigate this.…”

Section: Discussionmentioning

confidence: 99%

High-resolution dynamic MR imaging of the thorax for respiratory motion correction of PET using groupwise manifold alignment

Baumgartner

Kolbitsch

Balfour

et al. 2014

Medical Image Analysis

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Respiratory motion is a complicating factor in PET imaging as it leads to blurring of the reconstructed images which adversely affects disease diagnosis and staging. Existing motion correction techniques are often based on 1D navigators which cannot capture the inter- and intra-cycle variabilities that may occur in respiration. MR imaging is an attractive modality for estimating such motion more accurately, and the recent emergence of hybrid PET/MR systems allows the combination of the high molecular sensitivity of PET with the versatility of MR. However, current MR imaging techniques cannot achieve good image contrast inside the lungs in 3D. 2D slices, on the other hand, have excellent contrast properties inside the lungs due to the in-flow of previously unexcited blood, but lack the coverage of 3D volumes. In this work we propose an approach for the robust, navigator-less reconstruction of dynamic 3D volumes from 2D slice data. Our technique relies on the fact that data acquired at different slice positions have similar low-dimensional representations which can be extracted using manifold learning. By aligning these manifolds we are able to obtain accurate matchings of slices with regard to respiratory position. The approach naturally models all respiratory variabilities. We compare our method against two recently proposed MR slice stacking methods for the correction of PET data: a technique based on a 1D pencil beam navigator, and an image-based technique. On synthetic data with a known ground truth our proposed technique produces significantly better reconstructions than all other examined techniques. On real data without a known ground truth the method gives the most plausible reconstructions and high consistency of reconstruction. Lastly, we demonstrate how our method can be applied for the respiratory motion correction of simulated PET/MR data.

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“…6 For PET-MR imaging, precalibrated motion models are based on near real-time MR images acquired before the simultaneous PET-MR acquisition. This approach has been applied in MR-based PET simulation studies [24][25][26][27][28][29] with healthy volunteer MR data. 3D T1-weighted turbo field echo (TFE) MR images were acquired using parallel imaging (SENSE) with an acceleration factor of 8, so that each whole-thorax volume is acquired in 0.7 seconds.…”

Section: Respiratory Motionmentioning

confidence: 99%

“…Polycarpou and colleagues 26,27 and Tsoumpas and colleagues 29 also performed a comparison between the 2 approaches using OSEM reconstruction in an MR-based PET simulation study. They found that MCIR achieves better contrast and smaller bias in low-activity regions compared with PRR, but has lower SNR.…”

Section: Comparison Between Motion-compensated Image Reconstruction Amentioning

confidence: 99%

MR-Based Cardiac and Respiratory Motion-Compensation Techniques for PET-MR Imaging

et al. 2016

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Cardiac and respiratory motion cause image quality degradation in PET imaging, affecting diagnostic accuracy of the images. Whole-body simultaneous PET-MR scanners allow for using motion information estimated from MR images to correct PET data and produce motion-compensated PET images. This article reviews methods that have been proposed to estimate motion from MR images and different techniques to include this information in PET reconstruction, in order to overcome the problem of cardiac and respiratory motion in PET-MR imaging. MR-based motion correction techniques significantly increase lesion detectability and contrast, and also improve accuracy of uptake values in PET images.

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Statistical evaluation of PET motion correction methods using MR derived motion fields

Cited by 6 publications

References 30 publications

MR‐assisted PET respiratory motion correction using deep‐learning based short‐scan motion fields

MR‐assisted PET respiratory motion correction using deep‐learning based short‐scan motion fields

High-resolution dynamic MR imaging of the thorax for respiratory motion correction of PET using groupwise manifold alignment

MR-Based Cardiac and Respiratory Motion-Compensation Techniques for PET-MR Imaging

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