Evaluation of a direct motion estimation/correction method in respiratory-gated PET/MRI with motion-adjusted attenuation

Alexandre Bousse; Richard Manber; Beverley F Holman; David Atkinson; Simon Arridge; Sébastien Ourselin; Brian F Hutton; Kris Thielemans

doi:10.1002/mp.12253

Evaluation of a direct motion estimation/correction method in respiratory-gated PET/MRI with motion-adjusted attenuation

Med Phys. 2017 Jun;44(6):2379-2390. doi: 10.1002/mp.12253. Epub 2017 May 12.

Authors

Alexandre Bousse¹, Richard Manber¹, Beverley F Holman¹, David Atkinson², Simon Arridge³, Sébastien Ourselin³, Brian F Hutton^{1

4}, Kris Thielemans¹

Affiliations

¹ Institute of Nuclear Medicine, University College London, London, NW1, 2BU, UK.
² Centre for Medical Imaging, University College London, London, NW1, 2PG, UK.
³ Centre for Medical Image Computing, University College London, London, WC1E, 7JE, UK.
⁴ Centre for Medical Radiation Physics, University of Wollongong, Wollongong, NSW, 2522, Australia.

PMID: 28375560
DOI: 10.1002/mp.12253

Abstract

Purpose: Respiratory motion compensation in PET/CT and PET/MRI is essential as motion is a source of image degradation (motion blur, attenuation artifacts). In previous work, we developed a direct method for joint image reconstruction/motion estimation (JRM) for attenuation-corrected (AC) respiratory-gated PET, which uses a single attenuation-map (μ-map). This approach was successfully implemented for respiratory-gated PET/CT, but since it relied on an accurate μ-map for motion estimation, the question of its applicability in PET/MRI is open. The purpose of this work is to investigate the feasibility of JRM in PET/MRI and to assess the robustness of the motion estimation when a degraded μ-map is used.

Methods: We performed a series of JRM reconstructions from simulated PET data using a range of simulated Dixon MRI sequence derived μ-maps with wrong attenuation values in the lungs, from -100% (no attenuation) to +100% (double attenuation), as well as truncated arms. We compared the estimated motions with the one obtained from JRM in ideal conditions (no noise, true μ-map as an input). We also applied JRM on 4 patient datasets of the chest, 3 of them containing hot lesions. Patient list-mode data were gated using a principal component analysis method. We compared SUV_max values of the JRM reconstructed activity images and non motion-corrected images. We also assessed the estimated motion fields by comparing the deformed JRM-reconstructed activity with individually non-AC reconstructed gates.

Results: Experiments on simulated data showed that JRM-motion estimation is robust to μ-map degradation in the sense that it produces motion fields similar to the ones obtained when using the true μ-map, regardless of the attenuation errors in the lungs (< 0.5% mean absolute difference with the reference motion field). When using a μ-map with truncated arms, JRM estimates a motion field that stretches the μ-map in order to match the projection data. Results on patient datasets showed that using JRM improves the SUV_max values of hot lesions significantly and suppresses motion blur. When the estimated motion fields are applied to the reconstructed activity, the deformed images are geometrically similar to the non-AC individually reconstructed gates.

Conclusion: Motion estimation by JRM is robust to variation of the attenuation values in the lungs. JRM successfully compensates for motion when applied to PET/MRI clinical datasets. It provides a potential alternative to existing methods where the motion fields are pre-estimated from separate MRI measurements.

Keywords: PET/MRI; attenuation correction; direct motion estimation; image reconstruction; maximum-likelihood; respiratory-gated PET.

MeSH terms

Algorithms*
Humans
Magnetic Resonance Imaging
Motion
Positron Emission Tomography Computed Tomography*
Positron-Emission Tomography