Joint Compensation of Motion and Partial Volume Effects by Iterative Deconvolution Incorporating Wavelet-Based Denoising in Oncologic Pet/Ct Imaging

Science Communicator Platform

Stay connected! Follow us on X network (Twitter):

Share By

Joint Compensation of Motion and Partial Volume Effects by Iterative Deconvolution Incorporating Wavelet-Based Denoising in Oncologic Pet/Ct Imaging Publisher Pubmed

Rezaei S^{1, 2} ; Ghafarian P^{3, 4} ; Jha AK^{5, 6} ; Rahmim A^{7, 8} ; Sarkar S² ; Ay MR^{1, 2}

Source: Physica Medica Published:2019

Abstract

Objectives: We aim to develop and rigorously evaluate an image-based deconvolution method to jointly compensate respiratory motion and partial volume effects (PVEs) for quantitative oncologic PET imaging, including studying the impact of various reconstruction algorithms on quantification performance. Procedures: An image-based deconvolution method that incorporated wavelet-based denoising within the Lucy-Richardson algorithm was implemented and assessed. The method was evaluated using phantom studies with signal-to-background ratios (SBR) of 4 and 8, and clinical data of 10 patients with 42 lung lesions ≤30 mm in diameter. In each study, PET images were reconstructed using four different algorithms: OSEM-basic, PSF, TOF, and TOFPSF. The performance was quantified using contrast recovery (CR), coefficient of variation (COV) and contrast-to-noise-ratio (CNR) metrics. Further, in each study, variabilities arising due to the four different reconstruction algorithms were assessed. Results: In phantom studies, incorporation of wavelet-based denoising improved COV in all cases. Processing images using proposed method yielded significantly higher CR and CNR particularly in small spheres, for all reconstruction algorithms and all SBRs (P < 0.05). In patient studies, processing images using the proposed method yielded significantly higher CR and CNR (P < 0.05). The choice of the reconstruction algorithm impacted quantification performance for changes in motion amplitude, tumor size and SBRs. Conclusions: Our results provide strong evidence that the proposed joint-compensation method can yield improved PET quantification. The choice of the reconstruction algorithm led to changes in quantitative accuracy, emphasizing the need to carefully select the right combination of reconstruction-image-based compensation methods. © 2019

Related Docs

View other Related Docs

1. Impact of Various Image Reconstruction Methods on Joint Compensation of Respiratory Motion and Partial Volume Effects in Whole-Body18f-Fdg Pet/Ct Imaging: Patients With Non-Small Cell Lung Cancer, Iranian South Medical Journal (2022)

2. The Impact of Iterative Reconstruction Protocol, Signal-To-Background Ratio and Background Activity on Measurement of Pet Spatial Resolution, Japanese Journal of Radiology (2020)

3. Quantification and Reduction of Respiratory Induced Artifacts in Positron Emission Tomography/Computed Tomography Using the Time-Of-Flight Technique, Nuclear Medicine Communications (2017)

Experts (# of related papers)

View all Related Experts

Mohammad Reza Ay (13)

Parham Geramifar (3)

Other Related Docs

4. Role of Lesion-To-Background Activity Ratio and Background Activity in Optimization of Reconstruction Protocols for Fdg Pet/Ct Images of Overweight Patients: A Phantom Study, Iranian Journal of Radiology (2023)

5. Impact of Image Reconstruction Methods on Quantitative Accuracy and Variability of Fdg-Pet Volumetric and Textural Measures in Solid Tumors, European Radiology (2019)

6. Reducing Scan Time Using Time-Of-Flight Protocol in Clinical [18F]Fdg-Pet/Ct Imaging: A Feasibility Study, Iranian Journal of Nuclear Medicine (2023)

7. Impact of Time-Of-Flight and Point-Spread-Function for Respiratory Artifact Reduction in Pet/Ct Imaging: Focus on Standardized Uptake Value, Tanaffos (2017)

8. Quantification of the Impact of Tof and Psf on Pet Images Using the Noise-Matching Concept: Clinical and Phantom Study, Nuclear Science and Techniques (2017)

9. The Influence of Using Different Reconstruction Algorithms on Sensitivity of Quantitative 18F-Fdg-Pet Volumetric Measures to Background Activity Variation, Iranian Journal of Nuclear Medicine (2018)

10. Impact of Random and Scattered Coincidences From Outside of Field of View on Positron Emission Tomography/Computed Tomography Imaging With Different Reconstruction Protocols, Nuclear Science and Techniques (2023)

11. Multicenter Quantitative 18F-Fluorodeoxyglucose Positron Emission Tomography Performance Harmonization: Use of Hottest Voxels Towards More Robust Quantification, Quantitative Imaging in Medicine and Surgery (2023)

12. Deep Learning-Based Partial Volume Correction in Standard and Low-Dose Positron Emission Tomography-Computed Tomography Imaging, Quantitative Imaging in Medicine and Surgery (2024)

13. Simultaneous Respiratory Motion Correction and Image Reconstruction in 4D-Multi Pinhole Small Animal Spect, Medical Physics (2019)

14. Towards Quantitative Small-Animal Imaging on Hybrid Pet/Ct and Pet/Mri Systems, Clinical and Translational Imaging (2020)

15. The Impact of Image Reconstruction Settings on 18F-Fdg Pet Radiomic Features: Multi-Scanner Phantom and Patient Studies, European Radiology (2017)

16. Synergistic Impact of Motion and Acquisition/Reconstruction Parameters on 18F-Fdg Pet Radiomic Features in Non-Small Cell Lung Cancer: Phantom and Clinical Studies, Medical Physics (2022)

17. Optimizing Pet-Ct Image Reconstruction Parameters for Diagnostic Imaging Using Non-Tof Algorithms, Biochemical and Cellular Archives (2018)

18. Enhancing Radiomics Robustness Using Bayesian Penalized Likelihood Pet Reconstruction: Application to Phantom and Non-Small Cell Lung Cancer Patient Studies, BMC Medical Imaging (2025)

19. Pet Nema Iq Phantom Dataset: Image Reconstruction Settings for Quantitative Pet Imaging, Data in Brief (2021)

20. Attention-Based Deep Neural Network for Partial Volume Correction in Brain 18F-Fdg Pet Imaging, Physica Medica (2024)

Style	Citing Format
MLA	Rezaei S, et al.. "Joint Compensation of Motion and Partial Volume Effects by Iterative Deconvolution Incorporating Wavelet-Based Denoising in Oncologic Pet/Ct Imaging." Physica Medica, vol. 68, no. , 2019, pp. 52-60.
APA	Rezaei S, Ghafarian P, Jha AK, Rahmim A, Sarkar S, Ay MR (2019). Joint Compensation of Motion and Partial Volume Effects by Iterative Deconvolution Incorporating Wavelet-Based Denoising in Oncologic Pet/Ct Imaging. Physica Medica, 68(), 52-60.
Chicago	Rezaei S, Ghafarian P, Jha AK, Rahmim A, Sarkar S, Ay MR. "Joint Compensation of Motion and Partial Volume Effects by Iterative Deconvolution Incorporating Wavelet-Based Denoising in Oncologic Pet/Ct Imaging." Physica Medica 68, no. (2019): 52-60.
Harvard	Rezaei S et al. (2019) 'Joint Compensation of Motion and Partial Volume Effects by Iterative Deconvolution Incorporating Wavelet-Based Denoising in Oncologic Pet/Ct Imaging', Physica Medica, 68(), pp. 52-60.
Vancouver	Rezaei S, Ghafarian P, Jha AK, Rahmim A, Sarkar S, Ay MR. Joint Compensation of Motion and Partial Volume Effects by Iterative Deconvolution Incorporating Wavelet-Based Denoising in Oncologic Pet/Ct Imaging. Physica Medica. 2019;68():52-60.
BibTex	@article{ author = {Rezaei S and Ghafarian P and Jha AK and Rahmim A and Sarkar S and Ay MR}, title = {Joint Compensation of Motion and Partial Volume Effects by Iterative Deconvolution Incorporating Wavelet-Based Denoising in Oncologic Pet/Ct Imaging}, journal = {Physica Medica}, volume = {68}, number = {}, pages = {52-60}, year = {2019} }
RIS	TY - JOUR AU - Rezaei S AU - Ghafarian P AU - Jha AK AU - Rahmim A AU - Sarkar S AU - Ay MR TI - Joint Compensation of Motion and Partial Volume Effects by Iterative Deconvolution Incorporating Wavelet-Based Denoising in Oncologic Pet/Ct Imaging JO - Physica Medica VL - 68 IS - SP - 52 EP - 60 PY - 2019 ER -

Science Communicator Platform

Authors

Abstract