Related papers: Highly efficient non-rigid registration in k-space with application to cardiac Magnetic Resonance Imaging

Highly efficient non-rigid registration in k-space with application to cardiac Magnetic Resonance Imaging

URL: http://arxiv.org/abs/2410.18834v1
Date: Thu, 24 Oct 2024 15:19:59 GMT
Title: Highly efficient non-rigid registration in k-space with application to cardiac Magnetic Resonance Imaging
Authors: Aya Ghoul, Kerstin Hammernik, Andreas Lingg, Patrick Krumm, Daniel Rueckert, Sergios Gatidis, Thomas Küstner,
Abstract summary: We propose a novel self-supervised deep learning-based framework, dubbed the Local-All Pass Attention Network (LAPANet) for non-rigid motion estimation. LAPANet was evaluated on cardiac motion estimation across various sampling trajectories and acceleration rates. The achieved high temporal resolution (less than 5 ms) for non-rigid motion opens new avenues for motion detection, tracking and correction in dynamic and real-time MRI applications.
Score: 10.618048010632728
License:
Abstract: In Magnetic Resonance Imaging (MRI), high temporal-resolved motion can be useful for image acquisition and reconstruction, MR-guided radiotherapy, dynamic contrast-enhancement, flow and perfusion imaging, and functional assessment of motion patterns in cardiovascular, abdominal, peristaltic, fetal, or musculoskeletal imaging. Conventionally, these motion estimates are derived through image-based registration, a particularly challenging task for complex motion patterns and high dynamic resolution. The accelerated scans in such applications result in imaging artifacts that compromise the motion estimation. In this work, we propose a novel self-supervised deep learning-based framework, dubbed the Local-All Pass Attention Network (LAPANet), for non-rigid motion estimation directly from the acquired accelerated Fourier space, i.e. k-space. The proposed approach models non-rigid motion as the cumulative sum of local translational displacements, following the Local All-Pass (LAP) registration technique. LAPANet was evaluated on cardiac motion estimation across various sampling trajectories and acceleration rates. Our results demonstrate superior accuracy compared to prior conventional and deep learning-based registration methods, accommodating as few as 2 lines/frame in a Cartesian trajectory and 3 spokes/frame in a non-Cartesian trajectory. The achieved high temporal resolution (less than 5 ms) for non-rigid motion opens new avenues for motion detection, tracking and correction in dynamic and real-time MRI applications.

Related papers

KFD-NeRF: Rethinking Dynamic NeRF with Kalman Filter [49.85369344101118]
We introduce KFD-NeRF, a novel dynamic neural radiance field integrated with an efficient and high-quality motion reconstruction framework based on Kalman filtering. Our key idea is to model the dynamic radiance field as a dynamic system whose temporally varying states are estimated based on two sources of knowledge: observations and predictions. Our KFD-NeRF demonstrates similar or even superior performance within comparable computational time and state-of-the-art view synthesis performance with thorough training.
arXiv Detail & Related papers (2024-07-18T05:48:24Z)
Attention-aware non-rigid image registration for accelerated MR imaging [10.47044784972188]
We introduce an attention-aware deep learning-based framework that can perform non-rigid pairwise registration for fully sampled and accelerated MRI. We extract local visual representations to build similarity maps between the registered image pairs at multiple resolution levels. We demonstrate that our model derives reliable and consistent motion fields across different sampling trajectories.
arXiv Detail & Related papers (2024-04-26T14:25:07Z)
Motion-adaptive Separable Collaborative Filters for Blind Motion Deblurring [71.60457491155451]
Eliminating image blur produced by various kinds of motion has been a challenging problem. We propose a novel real-world deblurring filtering model called the Motion-adaptive Separable Collaborative Filter. Our method provides an effective solution for real-world motion blur removal and achieves state-of-the-art performance.
arXiv Detail & Related papers (2024-04-19T19:44:24Z)
Volumetric Reconstruction Resolves Off-Resonance Artifacts in Static and Dynamic PROPELLER MRI [76.60362295758596]
Off-resonance artifacts in magnetic resonance imaging (MRI) are visual distortions that occur when the actual resonant frequencies of spins within the imaging volume differ from the expected frequencies used to encode spatial information. We propose to resolve these artifacts by lifting the 2D MRI reconstruction problem to 3D, introducing an additional "spectral" dimension to model this off-resonance.
arXiv Detail & Related papers (2023-11-22T05:44:51Z)
MomentaMorph: Unsupervised Spatial-Temporal Registration with Momenta, Shooting, and Correction [12.281250177881445]
We introduce a novel framework for Lagrangian motion estimation in the presence of repetitive patterns and large motion. The results on a 2D synthetic dataset and a real 3D tMRI dataset demonstrate our method's efficiency.
arXiv Detail & Related papers (2023-08-05T20:32:30Z)
Unsupervised Landmark Detection Based Spatiotemporal Motion Estimation for 4D Dynamic Medical Images [16.759486905827433]
We provide a novel motion estimation framework of Dense-Sparse-Dense (DSD), which comprises two stages. In the first stage, we process the raw dense image to extract sparse landmarks to represent the target organ anatomical topology. In the second stage, we derive the sparse motion displacement from the extracted sparse landmarks of two images of different time points.
arXiv Detail & Related papers (2021-09-30T02:06:02Z)
LAPNet: Non-rigid Registration derived in k-space for Magnetic Resonance Imaging [28.404584219735074]
Motion correction techniques have been proposed to compensate for these types of motion during thoracic scans. A particular interest and challenge lie in the derivation of reliable non-rigid motion fields from the undersampled motion-resolved data. We propose a deep-learning based approach to perform fast and accurate non-rigid registration from the undersampled k-space data.
arXiv Detail & Related papers (2021-07-19T15:39:23Z)
DeepTag: An Unsupervised Deep Learning Method for Motion Tracking on Cardiac Tagging Magnetic Resonance Images [10.434681088538866]
We propose a novel deep learning-based fully unsupervised method for in vivo motion tracking on t-MRI images. Our method has been validated on a representative clinical t-MRI dataset.
arXiv Detail & Related papers (2021-03-04T00:42:11Z)
Motion Pyramid Networks for Accurate and Efficient Cardiac Motion Estimation [51.72616167073565]
We propose Motion Pyramid Networks, a novel deep learning-based approach for accurate and efficient cardiac motion estimation. We predict and fuse a pyramid of motion fields from multiple scales of feature representations to generate a more refined motion field. We then use a novel cyclic teacher-student training strategy to make the inference end-to-end and further improve the tracking performance.
arXiv Detail & Related papers (2020-06-28T21:03:19Z)
A Novel Approach for Correcting Multiple Discrete Rigid In-Plane Motions Artefacts in MRI Scans [63.28835187934139]
We propose a novel method for removing motion artefacts using a deep neural network with two input branches. The proposed method can be applied to artefacts generated by multiple movements of the patient.
arXiv Detail & Related papers (2020-06-24T15:25:11Z)
Microvascular Dynamics from 4D Microscopy Using Temporal Segmentation [81.30750944868142]
We are able to track changes in cerebral blood volume over time and identify spontaneous arterial dilations that propagate towards the pial surface. This new imaging capability is a promising step towards characterizing the hemodynamic response function upon which functional magnetic resonance imaging (fMRI) is based.
arXiv Detail & Related papers (2020-01-14T22:55:03Z)

This list is automatically generated from the titles and abstracts of the papers in this site.