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Main Authors: Huang, Jiahao, Wu, Yinzhe, Wang, Fanwen, Fang, Yingying, Nan, Yang, Alkan, Cagan, Abraham, Daniel, Liao, Congyu, Xu, Lei, Gao, Zhifan, Wu, Weiwen, Zhu, Lei, Chen, Zhaolin, Lally, Peter, Bangerter, Neal, Setsompop, Kawin, Guo, Yike, Rueckert, Daniel, Wang, Ge, Yang, Guang
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2401.16564
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author Huang, Jiahao
Wu, Yinzhe
Wang, Fanwen
Fang, Yingying
Nan, Yang
Alkan, Cagan
Abraham, Daniel
Liao, Congyu
Xu, Lei
Gao, Zhifan
Wu, Weiwen
Zhu, Lei
Chen, Zhaolin
Lally, Peter
Bangerter, Neal
Setsompop, Kawin
Guo, Yike
Rueckert, Daniel
Wang, Ge
Yang, Guang
author_facet Huang, Jiahao
Wu, Yinzhe
Wang, Fanwen
Fang, Yingying
Nan, Yang
Alkan, Cagan
Abraham, Daniel
Liao, Congyu
Xu, Lei
Gao, Zhifan
Wu, Weiwen
Zhu, Lei
Chen, Zhaolin
Lally, Peter
Bangerter, Neal
Setsompop, Kawin
Guo, Yike
Rueckert, Daniel
Wang, Ge
Yang, Guang
contents Magnetic Resonance Imaging (MRI) is a pivotal clinical diagnostic tool, yet its extended scanning times often compromise patient comfort and image quality, especially in volumetric, temporal and quantitative scans. This review elucidates recent advances in MRI acceleration via data and physics-driven models, leveraging techniques from algorithm unrolling models, enhancement-based methods, and plug-and-play models to the emerging full spectrum of generative model-based methods. We also explore the synergistic integration of data models with physics-based insights, encompassing the advancements in multi-coil hardware accelerations like parallel imaging and simultaneous multi-slice imaging, and the optimization of sampling patterns. We then focus on domain-specific challenges and opportunities, including image redundancy exploitation, image integrity, evaluation metrics, data heterogeneity, and model generalization. This work also discusses potential solutions and future research directions, with an emphasis on the role of data harmonization and federated learning for further improving the general applicability and performance of these methods in MRI reconstruction.
format Preprint
id arxiv_https___arxiv_org_abs_2401_16564
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Data and Physics driven Deep Learning Models for Fast MRI Reconstruction: Fundamentals and Methodologies
Huang, Jiahao
Wu, Yinzhe
Wang, Fanwen
Fang, Yingying
Nan, Yang
Alkan, Cagan
Abraham, Daniel
Liao, Congyu
Xu, Lei
Gao, Zhifan
Wu, Weiwen
Zhu, Lei
Chen, Zhaolin
Lally, Peter
Bangerter, Neal
Setsompop, Kawin
Guo, Yike
Rueckert, Daniel
Wang, Ge
Yang, Guang
Signal Processing
Magnetic Resonance Imaging (MRI) is a pivotal clinical diagnostic tool, yet its extended scanning times often compromise patient comfort and image quality, especially in volumetric, temporal and quantitative scans. This review elucidates recent advances in MRI acceleration via data and physics-driven models, leveraging techniques from algorithm unrolling models, enhancement-based methods, and plug-and-play models to the emerging full spectrum of generative model-based methods. We also explore the synergistic integration of data models with physics-based insights, encompassing the advancements in multi-coil hardware accelerations like parallel imaging and simultaneous multi-slice imaging, and the optimization of sampling patterns. We then focus on domain-specific challenges and opportunities, including image redundancy exploitation, image integrity, evaluation metrics, data heterogeneity, and model generalization. This work also discusses potential solutions and future research directions, with an emphasis on the role of data harmonization and federated learning for further improving the general applicability and performance of these methods in MRI reconstruction.
title Data and Physics driven Deep Learning Models for Fast MRI Reconstruction: Fundamentals and Methodologies
topic Signal Processing
url https://arxiv.org/abs/2401.16564