Respiratory Motion Compensation for PET/CT with Motion Information Derived from Matched Attenuation-Corrected Gated PET Data

Respiratory motion degrades the detection and quantification capabilities of PET/CT imaging. Moreover, mismatch between a fast helical CT image and a time-averaged PET image due to respiratory motion results in additional attenuation correction artifacts and inaccurate localization. Current motion compensation approaches typically have 3 limitations: the mismatch among respiration-gated PET images and the CT attenuation correction (CTAC) map can introduce artifacts in the gated PET reconstructions that can subsequently affect the accuracy of the motion estimation; sinogram-based correction approaches do not correct for intragate motion due to intracycle and intercycle breathing variations; and the mismatch between the PET motion compensation reference gate and the CT image can cause an additional CT-mismatch artifact. In this study, we established a motion correction framework to address these limitations. Methods: In the proposed framework, the combined emission–transmission reconstruction algorithm was used for phase-matched gated PET reconstructions to facilitate the motion model building. An event-by-event nonrigid respiratory motion compensation method with correlations between internal organ motion and external respiratory signals was used to correct both intracycle and intercycle breathing variations. The PET reference gate was automatically determined by a newly proposed CT-matching algorithm. We applied the new framework to 13 human datasets with 3 different radiotracers and 323 lesions and compared its performance with CTAC and non–attenuation correction (NAC) approaches. Validation using 4-dimensional CT was performed for one lung cancer dataset. Results: For the 10 18F-FDG studies, the proposed method outperformed (P < 0.006) both the CTAC and the NAC methods in terms of region-of-interest–based SUVmean, SUVmax, and SUV ratio improvements over no motion correction (SUVmean: 19.9% vs. 14.0% vs. 13.2%; SUVmax: 15.5% vs. 10.8% vs. 10.6%; SUV ratio: 24.1% vs. 17.6% vs. 16.2%, for the proposed, CTAC, and NAC methods, respectively). The proposed method increased SUV ratios over no motion correction for 94.4% of lesions, compared with 84.8% and 86.4% using the CTAC and NAC methods, respectively. For the 2 18F-fluoropropyl-(+)-dihydrotetrabenazine studies, the proposed method reduced the CT-mismatch artifacts in the lower lung where the CTAC approach failed and maintained the quantification accuracy of bone marrow where the NAC approach failed. For the 18F-FMISO study, the proposed method outperformed both the CTAC and the NAC methods in terms of motion estimation accuracy at 2 lung lesion locations. Conclusion: The proposed PET/CT respiratory event-by-event motion-correction framework with motion information derived from matched attenuation-corrected PET data provides image quality superior to that of the CTAC and NAC methods for multiple tracers.

[1]  G. J. Klein,et al.  Four-dimensional affine registration models for respiratory-gated PET , 2001 .

[2]  Chung Chan,et al.  Non-Rigid Event-by-Event Continuous Respiratory Motion Compensated List-Mode Reconstruction for PET , 2018, IEEE Transactions on Medical Imaging.

[3]  Vladimir Y. Panin,et al.  Reconstruction of uniform sensitivity emission image with partially known axial attenuation information in PET-CT scanners , 2012, 2012 IEEE Nuclear Science Symposium and Medical Imaging Conference Record (NSS/MIC).

[4]  Xiao Jin,et al.  List-mode reconstruction for the Biograph mCT with physics modeling and event-by-event motion correction , 2013, Physics in medicine and biology.

[5]  John L. Humm,et al.  PET of Hypoxia: Current and Future Perspectives , 2012, The Journal of Nuclear Medicine.

[6]  Johan Nuyts,et al.  Simultaneous reconstruction of the activity image and registration of the CT image in TOF-PET , 2016, 2013 IEEE Nuclear Science Symposium and Medical Imaging Conference (2013 NSS/MIC).

[7]  Huazhong Shu,et al.  Artifact Suppressed Dictionary Learning for Low-Dose CT Image Processing , 2014, IEEE Transactions on Medical Imaging.

[8]  Valentino Bettinardi,et al.  Generation of 4-Dimensional CT Images Based on 4-Dimensional PET–Derived Motion Fields , 2013, The Journal of Nuclear Medicine.

[9]  A J Reader,et al.  List-mode-based reconstruction for respiratory motion correction in PET using non-rigid body transformations , 2007, Physics in medicine and biology.

[10]  Daniel Rueckert,et al.  Nonrigid registration using free-form deformations: application to breast MR images , 1999, IEEE Transactions on Medical Imaging.

[11]  C. Ling,et al.  Effect of respiratory gating on quantifying PET images of lung cancer. , 2002, Journal of nuclear medicine : official publication, Society of Nuclear Medicine.

[12]  Yuji Nakamoto,et al.  Clinically significant inaccurate localization of lesions with PET/CT: frequency in 300 patients. , 2003, Journal of nuclear medicine : official publication, Society of Nuclear Medicine.

[13]  Kehong Yuan,et al.  Respiratory motion blur identification and reduction in ungated thoracic PET imaging , 2011, Physics in medicine and biology.

[14]  Dustin Scheinost,et al.  Unified Framework for Development, Deployment and Robust Testing of Neuroimaging Algorithms , 2011, Neuroinformatics.

[15]  Maurizio Conti,et al.  Quantitative Accuracy and Lesion Detectability of Low-Dose 18F-FDG PET for Lung Cancer Screening , 2017, The Journal of Nuclear Medicine.

[16]  Richard E Carson,et al.  In Vivo Imaging of Endogenous Pancreatic β-Cell Mass in Healthy and Type 1 Diabetic Subjects Using 18F-Fluoropropyl-Dihydrotetrabenazine and PET , 2012, The Journal of Nuclear Medicine.

[17]  M E Casey,et al.  Simultaneous reconstruction of emission activity and attenuation coefficient distribution from TOF data, acquired with external transmission source , 2013, Physics in medicine and biology.

[18]  Cyrill Burger,et al.  Respiration-induced attenuation artifact at PET/CT: technical considerations. , 2003, Radiology.

[19]  Tim Mulnix,et al.  Investigation of Sub-Centimeter Lung Nodule Quantification for Low-Dose PET , 2018, IEEE Transactions on Radiation and Plasma Medical Sciences.

[20]  Paul E Kinahan,et al.  The impact of respiratory motion on tumor quantification and delineation in static PET/CT imaging , 2009, Physics in medicine and biology.