Accelerated Patient-specific Non-Cartesian MRI Reconstruction using Implicit Neural Representations
- URL: http://arxiv.org/abs/2503.05051v1
- Date: Fri, 07 Mar 2025 00:05:43 GMT
- Title: Accelerated Patient-specific Non-Cartesian MRI Reconstruction using Implicit Neural Representations
- Authors: Di Xu, Hengjie Liu, Xin Miao, Daniel O'Connor, Jessica E. Scholey, Wensha Yang, Mary Feng, Michael Ohliger, Hui Lin, Dan Ruan, Yang Yang, Ke Sheng,
- Abstract summary: We develop a novel generative-adversarially trained implicit neural representations (k-GINR) for de novo undersampled non-Cartesian k-space reconstruction.<n>k-GINR consistently outperformed the baselines with a larger performance advantage observed at very high accelerations.
- Score: 8.781276186760962
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: The scanning time for a fully sampled MRI can be undesirably lengthy. Compressed sensing has been developed to minimize image artifacts in accelerated scans, but the required iterative reconstruction is computationally complex and difficult to generalize on new cases. Image-domain-based deep learning methods (e.g., convolutional neural networks) emerged as a faster alternative but face challenges in modeling continuous k-space, a problem amplified with non-Cartesian sampling commonly used in accelerated acquisition. In comparison, implicit neural representations can model continuous signals in the frequency domain and thus are compatible with arbitrary k-space sampling patterns. The current study develops a novel generative-adversarially trained implicit neural representations (k-GINR) for de novo undersampled non-Cartesian k-space reconstruction. k-GINR consists of two stages: 1) supervised training on an existing patient cohort; 2) self-supervised patient-specific optimization. In stage 1, the network is trained with the generative-adversarial network on diverse patients of the same anatomical region supervised by fully sampled acquisition. In stage 2, undersampled k-space data of individual patients is used to tailor the prior-embedded network for patient-specific optimization. The UCSF StarVIBE T1-weighted liver dataset was evaluated on the proposed framework. k-GINR is compared with an image-domain deep learning method, Deep Cascade CNN, and a compressed sensing method. k-GINR consistently outperformed the baselines with a larger performance advantage observed at very high accelerations (e.g., 20 times). k-GINR offers great value for direct non-Cartesian k-space reconstruction for new incoming patients across a wide range of accelerations liver anatomy.
Related papers
- ContextMRI: Enhancing Compressed Sensing MRI through Metadata Conditioning [51.26601171361753]
We propose ContextMRI, a text-conditioned diffusion model for MRI that integrates granular metadata into the reconstruction process.<n>We show that increasing the fidelity of metadata, ranging from slice location and contrast to patient age, sex, and pathology, systematically boosts reconstruction performance.
arXiv Detail & Related papers (2025-01-08T05:15:43Z) - Re-Visible Dual-Domain Self-Supervised Deep Unfolding Network for MRI Reconstruction [48.30341580103962]
We propose a novel re-visible dual-domain self-supervised deep unfolding network to address these issues.
We design a deep unfolding network based on Chambolle and Pock Proximal Point Algorithm (DUN-CP-PPA) to achieve end-to-end reconstruction.
Experiments conducted on the fastMRI and IXI datasets demonstrate that our method significantly outperforms state-of-the-art approaches in terms of reconstruction performance.
arXiv Detail & Related papers (2025-01-07T12:29:32Z) - A Unified Model for Compressed Sensing MRI Across Undersampling Patterns [69.19631302047569]
Deep neural networks have shown great potential for reconstructing high-fidelity images from undersampled measurements.<n>Our model is based on neural operators, a discretization-agnostic architecture.<n>Our inference speed is also 1,400x faster than diffusion methods.
arXiv Detail & Related papers (2024-10-05T20:03:57Z) - Intraoperative Registration by Cross-Modal Inverse Neural Rendering [61.687068931599846]
We present a novel approach for 3D/2D intraoperative registration during neurosurgery via cross-modal inverse neural rendering.
Our approach separates implicit neural representation into two components, handling anatomical structure preoperatively and appearance intraoperatively.
We tested our method on retrospective patients' data from clinical cases, showing that our method outperforms state-of-the-art while meeting current clinical standards for registration.
arXiv Detail & Related papers (2024-09-18T13:40:59Z) - Learning to sample in Cartesian MRI [1.2432046687586285]
Shortening scanning times is crucial in clinical settings, as it increases patient comfort, decreases examination costs and improves throughput.
Recent advances in compressed sensing (CS) and deep learning allow accelerated MRI acquisition by reconstructing high-quality images from undersampled data.
This thesis explores two approaches to address this gap in the context of Cartesian MRI.
arXiv Detail & Related papers (2023-12-07T14:38:07Z) - Dual-Domain Self-Supervised Learning for Accelerated Non-Cartesian MRI
Reconstruction [14.754843942604472]
We present a fully self-supervised approach for accelerated non-Cartesian MRI reconstruction.
In training, the undersampled data are split into disjoint k-space domain partitions.
For the image-level self-supervision, we enforce appearance consistency obtained from the original undersampled data.
arXiv Detail & Related papers (2023-02-18T06:11:49Z) - Learning Optimal K-space Acquisition and Reconstruction using
Physics-Informed Neural Networks [46.751292014516025]
Deep neural networks have been applied to reconstruct undersampled k-space data and have shown improved reconstruction performance.
This work proposes a novel framework to learn k-space sampling trajectories by considering it as an Ordinary Differential Equation (ODE) problem.
Experiments were conducted on different in-viv datasets (textite.g., brain and knee images) acquired with different sequences.
arXiv Detail & Related papers (2022-04-05T20:28:42Z) - InDuDoNet+: A Model-Driven Interpretable Dual Domain Network for Metal
Artifact Reduction in CT Images [53.4351366246531]
We construct a novel interpretable dual domain network, termed InDuDoNet+, into which CT imaging process is finely embedded.
We analyze the CT values among different tissues, and merge the prior observations into a prior network for our InDuDoNet+, which significantly improve its generalization performance.
arXiv Detail & Related papers (2021-12-23T15:52:37Z) - Transfer Learning Enhanced Generative Adversarial Networks for
Multi-Channel MRI Reconstruction [3.5765797841178597]
Deep learning based generative adversarial networks (GAN) can effectively perform image reconstruction with under-sampled MR data.
It is difficult to obtain tens of thousands of raw patient data to train the model since saving k-space data is not in the routine clinical flow.
In this study, three novel applications were explored based on parallel imaging combined with the GAN model (PI-GAN) and transfer learning.
arXiv Detail & Related papers (2021-05-17T21:28:00Z) - Unpaired Deep Learning for Accelerated MRI using Optimal Transport
Driven CycleGAN [33.68599686848292]
We propose an unpaired deep learning approach using a optimal transport driven cycle-consistent generative adversarial network (OT-cycleGAN)
The proposed OT-cycleGAN architecture is rigorously derived from a dual formulation of the optimal transport formulation using a specially designed penalized least squares cost.
arXiv Detail & Related papers (2020-08-29T12:02:49Z)
This list is automatically generated from the titles and abstracts of the papers in this site.
This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.