High-resolution dynamic MR imaging of the thorax for respiratory motion correction of PET using groupwise manifold alignment

Baumgartner, Christian F.; Kolbitsch, Christoph; Balfour, Daniel R.; Marsden, Paul; McClelland, Jamie R.; Rueckert, Daniel; King, Andrew P.

doi:10.1016/j.media.2014.05.010

Cited by 36 publications

(37 citation statements)

References 42 publications

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“…In Ref. 30, a slice stacking method was proposed using manifold learning. This technique was shown to outperform methods based on one-dimensional (1-D) pencil beam navigators and image-based methods.…”

Section: Introductionmentioning

confidence: 99%

Subject-specific four-dimensional liver motion modeling based on registration of dynamic MRI

et al. 2016

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Abstract. Magnetic resonance-guided high intensity focused ultrasound treatment of the liver is a promising noninvasive technique for ablation of liver lesions. For the technique to be used in clinical practice, however, the issue of liver motion needs to be addressed. A subject-specific four-dimensional liver motion model is presented that is created based on registration of dynamically acquired magnetic resonance data. This model can be used for predicting the tumor motion trajectory for treatment planning and to indicate the tumor position for treatment guidance. The performance of the model was evaluated on a dynamic scan series that was not used to build the model. The method achieved an average Dice coefficient of 0.93 between the predicted and actual liver profiles and an average vessel misalignment of 3.0 mm. The model performed robustly, with a small variation in the results per subject. The results demonstrate the potential of the model to be used for MRI-guided treatment of liver lesions. Furthermore, the model can possibly be applied in other image-guided therapies, for instance radiotherapy of the liver.

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Section: Introductionmentioning

confidence: 99%

Subject-specific four-dimensional liver motion modeling based on registration of dynamic MRI

et al. 2016

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“…In turn, such differences result in errors associated with the derivation of DMs from 4D CT frames for PET motion correction (12,13). In the case of PET/MR systems, these 2 issues associated with 4D CT acquisitions are irrelevant, given the nonionizing nature of MR acquisitions, their good tissue contrast even in the lungs as demonstrated using newly developed algorithms (14), and the capability of simultaneous PET and MR acquisitions.…”

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confidence: 99%

Reconstruction-Incorporated Respiratory Motion Correction in Clinical Simultaneous PET/MR Imaging for Oncology Applications

Fayad

Schmidt²,

Wuerslin³

et al. 2015

J Nucl Med

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Simultaneous PET and MR imaging is a promising new technique allowing the fusion of functional (PET) and anatomic/functional (MR) information. In the thoracic-abdominal regions, respiratory motion is a major challenge leading to reduced quantitative and qualitative image accuracy. Correction methodologies include the use of gated frames that lead to low signal-to-noise ratio considering the associated low statistics. More advanced correction approaches, previously developed for PET/CT imaging, consist of either registering all the reconstructed gated frames to the reference frame or incorporating motion parameters into the iterative reconstruction process to produce a single motioncompensated PET image. The goal of this work was to compare these two-previously implemented in PET/CT-correction approaches within the context of PET/MR motion correction for oncology applications using clinical 4-dimensional PET/MR acquisitions. Two different correction approaches were evaluated comparing the incorporation of elastic transformations extracted from 4-dimensional MR imaging datasets during PET list-mode image reconstruction to a postreconstruction imagebased approach. Methods: Eleven patient datasets acquired on a PET/MR system were used. T1-weighted 4D MR images were registered to the end-expiration image using a nonrigid B-spline registration algorithm to derive deformation matrices accounting for respiratory motion. The derived matrices were subsequently incorporated within a PET image reconstruction of the original emission list-mode data (reconstruction space [RS] method). The corrected images were compared with those produced by applying the deformation matrices in the image space (IS method) followed by summing the realigned gated frames, as well as with uncorrected motion-averaged images. Results: Both correction techniques led to significant improvement in accounting for respiratory motion artifacts when compared with uncorrected motionaveraged images. These improvements included signal-to-noise ratio (mean increase of 28.0% and 24.2% for the RS and IS methods, respectively), lesion size (reduction of 60.4% and 47.9%, respectively), lesion contrast (increase of 70.1% and 57.2%, respectively), and lesion position (changes of 60.9% and 46.7%, respectively). Conclusion: Our results demonstrate significant respiratory motion compensation using both methods, with superior results from a 4D PET RS approach.

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“…Unfortunately, 3-D imaging is not yet fast enough to capture cardiac motion directly. The frame rate for 3-D imaging can be up to 2 – 4 Hz [15], [17]. In addition, there is a trade-off between resolution and acquisition speed.…”

Section: Introductionmentioning

confidence: 99%

“…The third alternative to create 4-D MR images is slice-stacking [17], [24]–[30]. A stack of parallel slices is acquired with real-time MR imaging and retrospectively sorted into volumes.…”

Section: Introductionmentioning

confidence: 99%

An MR-Based Model for Cardio-Respiratory Motion Compensation of Overlays in X-Ray Fluoroscopy

Fischer

Faranesh

Pohl

et al. 2018

IEEE Trans. Med. Imaging

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In X-ray fluoroscopy, static overlays are used to visualize soft tissue. We propose a system for cardiac and respiratory motion compensation of these overlays. It consists of a 3-D motion model created from real-time MR imaging. Multiple sagittal slices are acquired and retrospectively stacked to consistent 3-D volumes. Slice stacking considers cardiac information derived from the ECG and respiratory information extracted from the images. Additionally, temporal smoothness of the stacking is enhanced. Motion is estimated from the MR volumes using deformable 3-D/3-D registration. The motion model itself is a linear direct correspondence model using the same surrogate signals as slice stacking. In X-ray fluoroscopy, only the surrogate signals need to be extracted to apply the motion model and animate the overlay in real time. For evaluation, points are manually annotated in oblique MR slices and in contrast-enhanced X-ray images. The 2-D Euclidean distance of these points is reduced from 3.85 mm to 2.75 mm in MR and from 3.0 mm to 1.8 mm in X-ray compared to the static baseline. Furthermore, the motion-compensated overlays are shown qualitatively as images and videos.

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High-resolution dynamic MR imaging of the thorax for respiratory motion correction of PET using groupwise manifold alignment

Cited by 36 publications

References 42 publications

Subject-specific four-dimensional liver motion modeling based on registration of dynamic MRI

Subject-specific four-dimensional liver motion modeling based on registration of dynamic MRI

Reconstruction-Incorporated Respiratory Motion Correction in Clinical Simultaneous PET/MR Imaging for Oncology Applications

An MR-Based Model for Cardio-Respiratory Motion Compensation of Overlays in X-Ray Fluoroscopy

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