Evaluation of MRI-derived surrogate signals to model respiratory motion

Tran, Huong Elena; Eiben, Björn; Wetscherek, Andreas; Oelfke, Uwe; Meedt, G.; Hawkes, David J.; McClelland, Jamie R.

doi:10.1088/2057-1976/ab944c

Cited by 18 publications

(24 citation statements)

References 62 publications

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“…Further reducing the dimensionality, [43] achieved 5 Hz with 2D input data, and [16] generated 3D volumes at 3.3 Hz (acquisition + reconstruction) with 1D input data. Slightly different type of methods are based on surrogate signal models [14], [15], [44]- [46] that -similarly to this work -also use a bi-linear motion model, but directly incorporate 1D surrogate signals in this model to infer 3D motion-fields from 1D input data. These methods can thus achieve high temporal resolution, but rely heavily on the quality of the motion surrogate.…”

Section: Discussionmentioning

confidence: 99%

“…In [13], a pre-trained 3D motion model was fit to incoming 2D cine-images to obtain fast motion estimates. Additionally, surrogate-driven motion models have been proposed that relate cine-MRI-derived surrogate signals to motion-fields [14], [15]. Another recent work [16] rapidly generates 3D MR-images by determining the best match between the current 1D motion state and 1D motion states in a 3D+t respiratory-resolved image reconstruction.…”

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confidence: 99%

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Real-time non-rigid 3D respiratory motion estimation for MR-guided radiotherapy using MR-MOTUS

Huttinga,

Bruijnen,

Berg

et al. 2021

Preprint

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The MR-Linac is a combination of an MRscanner and radiotherapy linear accelerator (Linac) which holds the promise to increase the precision of radiotherapy treatments with MR-guided radiotherapy by monitoring motion during radiotherapy with MRI, and adjusting the radiotherapy plan accordingly. Optimal MR-guidance for respiratory motion during radiotherapy requires MRbased 3D motion estimation with a latency of 200-500 ms. Currently this is still challenging since typical methods rely on MR-images, and are therefore limited to the 3D MRimaging latency. In this work, we present a method to perform non-rigid 3D respiratory motion estimation with 170 ms latency, including both acquisition and reconstruction. The proposed method called real-time low-rank MR-MOTUS reconstructs motion-fields directly from k-space data, and leverages an explicit low-rank decomposition of motionfields to split the large scale 3D+t motion-field reconstruction problem posed in our previous work into two parts: (I) a medium-scale offline preparation phase and (II) a smallscale online inference phase which exploits the results of the offline phase for real-time computations. The method was validated on free-breathing data of five volunteers, acquired with a 1.5T Elekta Unity MR-Linac. Results show that the reconstructed 3D motion-fields are anatomically plausible, highly correlated with a self-navigation motion surrogate (R = 0.975 ± 0.0110), and can be reconstructed with a total latency of 170 ms that is sufficient for real-time MR-guided abdominal radiotherapy.

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Section: Discussionmentioning

confidence: 99%

mentioning

confidence: 99%

Real-time non-rigid 3D respiratory motion estimation for MR-guided radiotherapy using MR-MOTUS

Huttinga,

Bruijnen,

Berg

et al. 2021

Preprint

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“…The spatial resolution of a two-dimensional navigator can be at 1.8 × 1.8 mm 2 with an expected temporal resolution no better than around 185 ms [ 32 ]. One advantage of the two-dimensional navigators is that multiple one-dimensional navigators can be extracted from distant points providing multiple surrogate signals for motion tracking, or an input for a more complete fully three-dimensional respiratory motion model [ 33 ]. The disadvantage of a two-dimensional navigator lies in the out-of-plane motion which a three-dimensional navigator can resolve effectively.…”

Section: Motion Trackingmentioning

confidence: 99%

Synergistic motion compensation strategies for positron emission tomography when acquired simultaneously with magnetic resonance imaging

Polycarpou

Soultanidis

Tsoumpas

2021

Phil. Trans. R. Soc. A.

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Subject motion in positron emission tomography (PET) is a key factor that degrades image resolution and quality, limiting its potential capabilities. Correcting for it is complicated due to the lack of sufficient measured PET data from each position. This poses a significant barrier in calculating the amount of motion occurring during a scan. Motion correction can be implemented at different stages of data processing either during or after image reconstruction, and once applied accurately can substantially improve image quality and information accuracy. With the development of integrated PET-MRI (magnetic resonance imaging) scanners, internal organ motion can be measured concurrently with both PET and MRI. In this review paper, we explore the synergistic use of PET and MRI data to correct for any motion that affects the PET images. Different types of motion that can occur during PET-MRI acquisitions are presented and the associated motion detection, estimation and correction methods are reviewed. Finally, some highlights from recent literature in selected human and animal imaging applications are presented and the importance of motion correction for accurate kinetic modelling in dynamic PET-MRI is emphasized. This article is part of the theme issue ‘Synergistic tomographic image reconstruction: part 2’.

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“…[13][14][15][16] TR 3D images still present insufficient spatiotemporal resolution 9 ; however, TR 2D cine-MRI can be acquired to describe cycle-to-cycle breathing variations. 17 To obtain 3D information on breathing organ motion based on 2D cine-MRI, different methods have been proposed in the literature, [18][19][20][21][22][23] generally relying on a global respiratory motion model 24 which establishes a correlation between a priori knowledge on the breathing motion (e.g., pretreatment 4D imaging) and a surrogate of respiration (e.g., image-based signals 25 ). The method by Paganelli et al, 26 recently validated on both computational and physical phantoms, 21,27 allows TR 3D reconstruction of respiratory motion without the need of previous RC (4D) imaging.…”

Section: Introductionmentioning

confidence: 99%

Time‐resolved MRI for off‐line treatment robustness evaluation in carbon‐ion radiotherapy of pancreatic cancer

et al. 2022

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In this study, we investigate the use of magnetic resonance imaging (MRI) for the clinical evaluation of gating treatment robustness in carbonion radiotherapy (CIRT) of pancreatic cancer. Indeed, MRI allows radiation-free repeated scans and fast dynamic sequences for time-resolved (TR) imaging (cine-MRI), providing information on inter-and intra-fraction cycle-to-cycle variations of respiratory motion. MRI can therefore support treatment planning and verification, overcoming the limitations of the current clinical standard, that is, four-dimensional computed tomography (4DCT), which describes an "average" breathing cycle neglecting breathing motion variability. Methods: We integrated a technique to generate a virtual CT (vCT) from 3D MRI with a method for 3D reconstruction from 2D cine-MRI, to produce TR vCTs for dose recalculations. For eight patients, the method allowed evaluating inter-fraction variations at end-exhale and intra-fraction cycle-to-cycle variability within the gating window in terms of tumor displacement and dose to the target and organs at risk. Results:The median inter-fraction tumor motion was in the range 3.33-12.16 mm, but the target coverage was robust (-0.4% median D 95% variation). Concerning cycle-to-cycle variations, the gating technique was effective in limiting tumor displacement (1.35 mm median gating motion) and corresponding dose variations (-3.9% median D 95% variation). The larger exposure of organs at risk (duodenum and stomach) was caused by inter-fraction motion, whereas intra-fraction cycle-to-cycle dose variations were limited. Conclusions: This study proposed a method for the generation of TR vCTs from MRI, which enabled an off -line evaluation of gating treatment robustness and suggested its feasibility to support treatment planning of pancreatic tumors in CIRT.

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Evaluation of MRI-derived surrogate signals to model respiratory motion

Cited by 18 publications

References 62 publications

Real-time non-rigid 3D respiratory motion estimation for MR-guided radiotherapy using MR-MOTUS

Real-time non-rigid 3D respiratory motion estimation for MR-guided radiotherapy using MR-MOTUS

Synergistic motion compensation strategies for positron emission tomography when acquired simultaneously with magnetic resonance imaging

Time‐resolved MRI for off‐line treatment robustness evaluation in carbon‐ion radiotherapy of pancreatic cancer

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