Literature DB >> 32048372

Artificial Intelligence for MR Image Reconstruction: An Overview for Clinicians.

Dana J Lin1, Patricia M Johnson2, Florian Knoll2, Yvonne W Lui1.   

Abstract

Artificial intelligence (AI) shows tremendous promise in the field of medical imaging, with recent breakthroughs applying deep-learning models for data acquisition, classification problems, segmentation, image synthesis, and image reconstruction. With an eye towards clinical applications, we summarize the active field of deep-learning-based MR image reconstruction. We review the basic concepts of how deep-learning algorithms aid in the transformation of raw k-space data to image data, and specifically examine accelerated imaging and artifact suppression. Recent efforts in these areas show that deep-learning-based algorithms can match and, in some cases, eclipse conventional reconstruction methods in terms of image quality and computational efficiency across a host of clinical imaging applications, including musculoskeletal, abdominal, cardiac, and brain imaging. This article is an introductory overview aimed at clinical radiologists with no experience in deep-learning-based MR image reconstruction and should enable them to understand the basic concepts and current clinical applications of this rapidly growing area of research across multiple organ systems.
© 2020 International Society for Magnetic Resonance in Medicine.

Entities:  

Keywords:  MRI; deep learning; image reconstruction

Mesh:

Year:  2020        PMID: 32048372      PMCID: PMC7423636          DOI: 10.1002/jmri.27078

Source DB:  PubMed          Journal:  J Magn Reson Imaging        ISSN: 1053-1807            Impact factor:   4.813


  54 in total

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Journal:  Magn Reson Med       Date:  1999-11       Impact factor: 4.668

2.  Simultaneous acquisition of spatial harmonics (SMASH): fast imaging with radiofrequency coil arrays.

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3.  Deep learning for undersampled MRI reconstruction.

Authors:  Chang Min Hyun; Hwa Pyung Kim; Sung Min Lee; Sungchul Lee; Jin Keun Seo
Journal:  Phys Med Biol       Date:  2018-06-25       Impact factor: 3.609

4.  Image feature analysis and computer-aided diagnosis in digital radiography. I. Automated detection of microcalcifications in mammography.

Authors:  H P Chan; K Doi; S Galhotra; C J Vyborny; H MacMahon; P M Jokich
Journal:  Med Phys       Date:  1987 Jul-Aug       Impact factor: 4.071

5.  Network Accelerated Motion Estimation and Reduction (NAMER): Convolutional neural network guided retrospective motion correction using a separable motion model.

Authors:  Melissa W Haskell; Stephen F Cauley; Berkin Bilgic; Julian Hossbach; Daniel N Splitthoff; Josef Pfeuffer; Kawin Setsompop; Lawrence L Wald
Journal:  Magn Reson Med       Date:  2019-05-02       Impact factor: 4.668

6.  Scan-specific robust artificial-neural-networks for k-space interpolation (RAKI) reconstruction: Database-free deep learning for fast imaging.

Authors:  Mehmet Akçakaya; Steen Moeller; Sebastian Weingärtner; Kâmil Uğurbil
Journal:  Magn Reson Med       Date:  2018-09-18       Impact factor: 4.668

7.  Learning a variational network for reconstruction of accelerated MRI data.

Authors:  Kerstin Hammernik; Teresa Klatzer; Erich Kobler; Michael P Recht; Daniel K Sodickson; Thomas Pock; Florian Knoll
Journal:  Magn Reson Med       Date:  2017-11-08       Impact factor: 4.668

8.  Super-resolution musculoskeletal MRI using deep learning.

Authors:  Akshay S Chaudhari; Zhongnan Fang; Feliks Kogan; Jeff Wood; Kathryn J Stevens; Eric K Gibbons; Jin Hyung Lee; Garry E Gold; Brian A Hargreaves
Journal:  Magn Reson Med       Date:  2018-03-26       Impact factor: 4.668

9.  Deep Generative Adversarial Neural Networks for Compressive Sensing MRI.

Authors:  Morteza Mardani; Enhao Gong; Joseph Y Cheng; Shreyas S Vasanawala; Greg Zaharchuk; Lei Xing; John M Pauly
Journal:  IEEE Trans Med Imaging       Date:  2018-07-23       Impact factor: 10.048

10.  Attenuation correction using 3D deep convolutional neural network for brain 18F-FDG PET/MR: Comparison with Atlas, ZTE and CT based attenuation correction.

Authors:  Paul Blanc-Durand; Maya Khalife; Brian Sgard; Sandeep Kaushik; Marine Soret; Amal Tiss; Georges El Fakhri; Marie-Odile Habert; Florian Wiesinger; Aurélie Kas
Journal:  PLoS One       Date:  2019-10-07       Impact factor: 3.240
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  11 in total

Review 1.  Pediatric magnetic resonance imaging: faster is better.

Authors:  Sebastian Gallo-Bernal; M Alejandra Bedoya; Michael S Gee; Camilo Jaimes
Journal:  Pediatr Radiol       Date:  2022-10-20

2.  Improving high frequency image features of deep learning reconstructions via k-space refinement with null-space kernel.

Authors:  Kanghyun Ryu; Cagan Alkan; Shreyas S Vasanawala
Journal:  Magn Reson Med       Date:  2022-04-15       Impact factor: 3.737

3.  Diagnostic interchangeability of deep convolutional neural networks reconstructed knee MR images: preliminary experience.

Authors:  Naveen Subhas; Hongyu Li; Mingrui Yang; Carl S Winalski; Joshua Polster; Nancy Obuchowski; Kenji Mamoto; Ruiying Liu; Chaoyi Zhang; Peizhou Huang; Sunil Kumar Gaire; Dong Liang; Bowen Shen; Xiaojuan Li; Leslie Ying
Journal:  Quant Imaging Med Surg       Date:  2020-09

Review 4.  The current and future roles of artificial intelligence in pediatric radiology.

Authors:  Jeffrey P Otjen; Michael M Moore; Erin K Romberg; Francisco A Perez; Ramesh S Iyer
Journal:  Pediatr Radiol       Date:  2021-05-27

Review 5.  Prospective Deployment of Deep Learning in MRI: A Framework for Important Considerations, Challenges, and Recommendations for Best Practices.

Authors:  Akshay S Chaudhari; Christopher M Sandino; Elizabeth K Cole; David B Larson; Garry E Gold; Shreyas S Vasanawala; Matthew P Lungren; Brian A Hargreaves; Curtis P Langlotz
Journal:  J Magn Reson Imaging       Date:  2020-08-24       Impact factor: 5.119

Review 6.  Coronary Magnetic Resonance Angiography in Chronic Coronary Syndromes.

Authors:  Reza Hajhosseiny; Camila Munoz; Gastao Cruz; Ramzi Khamis; Won Yong Kim; Claudia Prieto; René M Botnar
Journal:  Front Cardiovasc Med       Date:  2021-08-17

7.  A low-cost and shielding-free ultra-low-field brain MRI scanner.

Authors:  Yilong Liu; Alex T L Leong; Yujiao Zhao; Linfang Xiao; Henry K F Mak; Anderson Chun On Tsang; Gary K K Lau; Gilberto K K Leung; Ed X Wu
Journal:  Nat Commun       Date:  2021-12-14       Impact factor: 14.919

Review 8.  Medical imaging and nuclear medicine: a Lancet Oncology Commission.

Authors:  Hedvig Hricak; May Abdel-Wahab; Rifat Atun; Miriam Mikhail Lette; Diana Paez; James A Brink; Lluís Donoso-Bach; Guy Frija; Monika Hierath; Ola Holmberg; Pek-Lan Khong; Jason S Lewis; Geraldine McGinty; Wim J G Oyen; Lawrence N Shulman; Zachary J Ward; Andrew M Scott
Journal:  Lancet Oncol       Date:  2021-03-04       Impact factor: 41.316

9.  Applicability of deep learning-based reconstruction trained by brain and knee 3T MRI to lumbar 1.5T MRI.

Authors:  Nobuo Kashiwagi; Hisashi Tanaka; Yuichi Yamashita; Hiroto Takahashi; Yoshimori Kassai; Masahiro Fujiwara; Noriyuki Tomiyama
Journal:  Acta Radiol Open       Date:  2021-06-18

10.  CINENet: deep learning-based 3D cardiac CINE MRI reconstruction with multi-coil complex-valued 4D spatio-temporal convolutions.

Authors:  Thomas Küstner; Niccolo Fuin; Kerstin Hammernik; Aurelien Bustin; Haikun Qi; Reza Hajhosseiny; Pier Giorgio Masci; Radhouene Neji; Daniel Rueckert; René M Botnar; Claudia Prieto
Journal:  Sci Rep       Date:  2020-08-13       Impact factor: 4.379
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