Literature DB >> 33192036

Compressed Sensing: From Research to Clinical Practice with Deep Neural Networks.

Christopher M Sandino1, Joseph Y Cheng2, Feiyu Chen2, Morteza Mardani2, John M Pauly2, Shreyas S Vasanawala2.   

Abstract

Compressed sensing (CS) reconstruction methods leverage sparse structure in underlying signals to recover high-resolution images from highly undersampled measurements. When applied to magnetic resonance imaging (MRI), CS has the potential to dramatically shorten MRI scan times, increase diagnostic value, and improve overall patient experience. However, CS has several shortcomings which limit its clinical translation such as: 1) artifacts arising from inaccurate sparse modelling assumptions, 2) extensive parameter tuning required for each clinical application, and 3) clinically infeasible reconstruction times. Recently, CS has been extended to incorporate deep neural networks as a way of learning complex image priors from historical exam data. Commonly referred to as unrolled neural networks, these techniques have proven to be a compelling and practical approach to address the challenges of sparse CS. In this tutorial, we will review the classical compressed sensing formulation and outline steps needed to transform this formulation into a deep learning-based reconstruction framework. Supplementary open source code in Python will be used to demonstrate this approach with open databases. Further, we will discuss considerations in applying unrolled neural networks in the clinical setting.

Entities:  

Keywords:  clinical translation; compressed sensing; deep learning

Year:  2020        PMID: 33192036      PMCID: PMC7664163          DOI: 10.1109/MSP.2019.2950433

Source DB:  PubMed          Journal:  IEEE Signal Process Mag        ISSN: 1053-5888            Impact factor:   12.551


  22 in total

1.  SENSE: sensitivity encoding for fast MRI.

Authors:  K P Pruessmann; M Weiger; M B Scheidegger; P Boesiger
Journal:  Magn Reson Med       Date:  1999-11       Impact factor: 4.668

2.  Improved pediatric MR imaging with compressed sensing.

Authors:  Shreyas S Vasanawala; Marcus T Alley; Brian A Hargreaves; Richard A Barth; John M Pauly; Michael Lustig
Journal:  Radiology       Date:  2010-06-07       Impact factor: 11.105

3.  Regularization parameter selection for nonlinear iterative image restoration and MRI reconstruction using GCV and SURE-based methods.

Authors:  Sathish Ramani; Zhihao Liu; Jeffrey Rosen; Jon-Fredrik Nielsen; Jeffrey A Fessler
Journal:  IEEE Trans Image Process       Date:  2012-04-17       Impact factor: 10.856

4.  Undersampled radial MRI with multiple coils. Iterative image reconstruction using a total variation constraint.

Authors:  Kai Tobias Block; Martin Uecker; Jens Frahm
Journal:  Magn Reson Med       Date:  2007-06       Impact factor: 4.668

5.  Image reconstruction by domain-transform manifold learning.

Authors:  Bo Zhu; Jeremiah Z Liu; Stephen F Cauley; Bruce R Rosen; Matthew S Rosen
Journal:  Nature       Date:  2018-03-21       Impact factor: 49.962

6.  Clinical performance of high-resolution late gadolinium enhancement imaging with compressed sensing.

Authors:  Tamer A Basha; Mehmet Akçakaya; Charlene Liew; Connie W Tsao; Francesca N Delling; Gifty Addae; Long Ngo; Warren J Manning; Reza Nezafat
Journal:  J Magn Reson Imaging       Date:  2017-03-16       Impact factor: 4.813

7.  Variable-Density Single-Shot Fast Spin-Echo MRI with Deep Learning Reconstruction by Using Variational Networks.

Authors:  Feiyu Chen; Valentina Taviani; Itzik Malkiel; Joseph Y Cheng; Jonathan I Tamir; Jamil Shaikh; Stephanie T Chang; Christopher J Hardy; John M Pauly; Shreyas S Vasanawala
Journal:  Radiology       Date:  2018-07-24       Impact factor: 11.105

8.  ESPIRiT--an eigenvalue approach to autocalibrating parallel MRI: where SENSE meets GRAPPA.

Authors:  Martin Uecker; Peng Lai; Mark J Murphy; Patrick Virtue; Michael Elad; John M Pauly; Shreyas S Vasanawala; Michael Lustig
Journal:  Magn Reson Med       Date:  2014-03       Impact factor: 4.668

9.  Fast pediatric 3D free-breathing abdominal dynamic contrast enhanced MRI with high spatiotemporal resolution.

Authors:  Tao Zhang; Joseph Y Cheng; Aaron G Potnick; Richard A Barth; Marcus T Alley; Martin Uecker; Michael Lustig; John M Pauly; Shreyas S Vasanawala
Journal:  J Magn Reson Imaging       Date:  2013-12-21       Impact factor: 4.813

10.  Accelerating compressed sensing in parallel imaging reconstructions using an efficient circulant preconditioner for cartesian trajectories.

Authors:  Kirsten Koolstra; Jeroen van Gemert; Peter Börnert; Andrew Webb; Rob Remis
Journal:  Magn Reson Med       Date:  2018-08-07       Impact factor: 4.668
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  12 in total

1.  Reconstruction of undersampled 3D non-Cartesian image-based navigators for coronary MRA using an unrolled deep learning model.

Authors:  Mario O Malavé; Corey A Baron; Srivathsan P Koundinyan; Christopher M Sandino; Frank Ong; Joseph Y Cheng; Dwight G Nishimura
Journal:  Magn Reson Med       Date:  2020-02-03       Impact factor: 4.668

2.  On the shape of convolution kernels in MRI reconstruction: Rectangles versus ellipsoids.

Authors:  Rodrigo A Lobos; Justin P Haldar
Journal:  Magn Reson Med       Date:  2022-02-24       Impact factor: 4.668

3.  Utilizing the Wavelet Transform's Structure in Compressed Sensing.

Authors:  Nicholas Dwork; Daniel O'Connor; Corey A Baron; Ethan M I Johnson; Adam B Kerr; John M Pauly; Peder E Z Larson
Journal:  Signal Image Video Process       Date:  2021-03-09       Impact factor: 1.583

4.  Wasserstein GANs for MR Imaging: From Paired to Unpaired Training.

Authors:  Ke Lei; Morteza Mardani; John M Pauly; Shreyas S Vasanawala
Journal:  IEEE Trans Med Imaging       Date:  2020-12-29       Impact factor: 10.048

5.  Data-driven self-calibration and reconstruction for non-cartesian wave-encoded single-shot fast spin echo using deep learning.

Authors:  Feiyu Chen; Joseph Y Cheng; Valentina Taviani; Vipul R Sheth; Ryan L Brunsing; John M Pauly; Shreyas S Vasanawala
Journal:  J Magn Reson Imaging       Date:  2019-07-19       Impact factor: 4.813

6.  Accelerating cardiac cine MRI using a deep learning-based ESPIRiT reconstruction.

Authors:  Christopher M Sandino; Peng Lai; Shreyas S Vasanawala; Joseph Y Cheng
Journal:  Magn Reson Med       Date:  2020-07-22       Impact factor: 4.668

7.  Local perturbation responses and checkerboard tests: Characterization tools for nonlinear MRI methods.

Authors:  Chin-Cheng Chan; Justin P Haldar
Journal:  Magn Reson Med       Date:  2021-06-03       Impact factor: 3.737

8.  Analysis of deep complex-valued convolutional neural networks for MRI reconstruction and phase-focused applications.

Authors:  Elizabeth Cole; Joseph Cheng; John Pauly; Shreyas Vasanawala
Journal:  Magn Reson Med       Date:  2021-03-16       Impact factor: 3.737

Review 9.  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

10.  Free-breathing Accelerated Cardiac MRI Using Deep Learning: Validation in Children and Young Adults.

Authors:  Evan J Zucker; Christopher M Sandino; Aya Kino; Peng Lai; Shreyas S Vasanawala
Journal:  Radiology       Date:  2021-06-15       Impact factor: 29.146
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