Real-time 3D motion estimation from undersampled MRI using multi-resolution neural networks

Maarten L Terpstra; Matteo Maspero; Tom Bruijnen; Joost J C Verhoeff; Jan J W Lagendijk; Cornelis A T van den Berg

doi:10.1002/mp.15217

Real-time 3D motion estimation from undersampled MRI using multi-resolution neural networks

Med Phys. 2021 Nov;48(11):6597-6613. doi: 10.1002/mp.15217. Epub 2021 Oct 26.

Authors

Maarten L Terpstra^{1

2}, Matteo Maspero^{1

2}, Tom Bruijnen^{1

2}, Joost J C Verhoeff¹, Jan J W Lagendijk¹, Cornelis A T van den Berg^{1

2}

Affiliations

¹ Department of Radiotherapy, University Medical Center Utrecht, Utrecht, The Netherlands.
² Computational Imaging Group for MR Diagnostics & Therapy, Center for Image Sciences, University Medical Center Utrecht, Utrecht, The Netherlands.

Abstract

Purpose: To enable real-time adaptive magnetic resonance imaging-guided radiotherapy (MRIgRT) by obtaining time-resolved three-dimensional (3D) deformation vector fields (DVFs) with high spatiotemporal resolution and low latency ( $< 500$ ms). Theory and Methods: Respiratory-resolved $T_{1}$ -weighted 4D-MRI of 27 patients with lung cancer were acquired using a golden-angle radial stack-of-stars readout. A multiresolution convolutional neural network (CNN) called TEMPEST was trained on up to 32 $\times$ retrospectively undersampled MRI of 17 patients, reconstructed with a nonuniform fast Fourier transform, to learn optical flow DVFs. TEMPEST was validated using 4D respiratory-resolved MRI, a digital phantom, and a physical motion phantom. The time-resolved motion estimation was evaluated in-vivo using two volunteer scans, acquired on a hybrid MR-scanner with integrated linear accelerator. Finally, we evaluated the model robustness on a publicly-available four-dimensional computed tomography (4D-CT) dataset.

Results: TEMPEST produced accurate DVFs on respiratory-resolved MRI at 20-fold acceleration, with the average end-point-error $< 2$ mm, both on respiratory-sorted MRI and on a digital phantom. TEMPEST estimated accurate time-resolved DVFs on MRI of a motion phantom, with an error $< 2$ mm at 28 $\times$ undersampling. On two volunteer scans, TEMPEST accurately estimated motion compared to the self-navigation signal using 50 spokes per dynamic (366 $\times$ undersampling). At this undersampling factor, DVFs were estimated within 200 ms, including MRI acquisition. On fully sampled CT data, we achieved a target registration error of $1.87 \pm 1.65$ mm without retraining the model.

Conclusion: A CNN trained on undersampled MRI produced accurate 3D DVFs with high spatiotemporal resolution for MRIgRT.

Keywords: MR-Linac; MRI; MRI-guided radiotherapy; adaptive radiotherapy; artificial intelligence; deep learning; motion estimation; radiotherapy; registration.

MeSH terms

Humans
Imaging, Three-Dimensional
Magnetic Resonance Imaging*
Motion
Neural Networks, Computer*
Phantoms, Imaging
Respiration
Retrospective Studies

Abstract

MeSH terms

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