MRI Super-Resolution Through Generative Degradation Learning
Spatial resolution plays a critically important role in MRI for the precise delineation of the imaged tissues. Unfortunately, acquisitions with high spatial resolution require increased imaging time, which increases the potential of subject motion, and suffers from reduced signal-to-noise ratio (SNR...
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| Published in | Medical Image Computing and Computer Assisted Intervention - MICCAI 2021 Vol. 12906; pp. 430 - 440 |
|---|---|
| Main Authors | , , , |
| Format | Book Chapter Journal Article |
| Language | English |
| Published |
Switzerland
Springer International Publishing AG
01.01.2021
Springer International Publishing |
| Series | Lecture Notes in Computer Science |
| Subjects | |
| Online Access | Get full text |
| ISBN | 9783030872304 3030872300 |
| ISSN | 0302-9743 1611-3349 |
| DOI | 10.1007/978-3-030-87231-1_42 |
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| Abstract | Spatial resolution plays a critically important role in MRI for the precise delineation of the imaged tissues. Unfortunately, acquisitions with high spatial resolution require increased imaging time, which increases the potential of subject motion, and suffers from reduced signal-to-noise ratio (SNR). Super-resolution reconstruction (SRR) has recently emerged as a technique that allows for a trade-off between high spatial resolution, high SNR, and short scan duration. Deconvolution-based SRR has recently received significant interest due to the convenience of using the image space. The most critical factor to succeed in deconvolution is the accuracy of the estimated blur kernels that characterize how the image was degraded in the acquisition process. Current methods use handcrafted filters, such as Gaussian filters, to approximate the blur kernels, and have achieved promising SRR results. As the image degradation is complex and varies with different sequences and scanners, handcrafted filters, unfortunately, do not necessarily ensure the success of the deconvolution. We sought to develop a technique that enables accurately estimating blur kernels from the image data itself. We designed a deep architecture that utilizes an adversarial scheme with a generative neural network against its degradation counterparts. This design allows for the SRR tailored to an individual subject, as the training requires the scan-specific data only, i.e., it does not require auxiliary datasets of high-quality images, which are practically challenging to obtain. With this technique, we achieved high-quality brain MRI at an isotropic resolution of 0.125 cubic mm with six minutes of imaging time. Extensive experiments on both simulated low-resolution data and clinical data acquired from ten pediatric patients demonstrated that our approach achieved superior SRR results as compared to state-of-the-art deconvolution-based methods, while in parallel, at substantially reduced imaging time in comparison to direct high-resolution acquisitions. |
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| AbstractList | Spatial resolution plays a critically important role in MRI for the precise delineation of the imaged tissues. Unfortunately, acquisitions with high spatial resolution require increased imaging time, which increases the potential of subject motion, and suffers from reduced signal-to-noise ratio (SNR). Super-resolution reconstruction (SRR) has recently emerged as a technique that allows for a trade-off between high spatial resolution, high SNR, and short scan duration. Deconvolution-based SRR has recently received significant interest due to the convenience of using the image space. The most critical factor to succeed in deconvolution is the accuracy of the estimated blur kernels that characterize how the image was degraded in the acquisition process. Current methods use handcrafted filters, such as Gaussian filters, to approximate the blur kernels, and have achieved promising SRR results. As the image degradation is complex and varies with different sequences and scanners, handcrafted filters, unfortunately, do not necessarily ensure the success of the deconvolution. We sought to develop a technique that enables accurately estimating blur kernels from the image data itself. We designed a deep architecture that utilizes an adversarial scheme with a generative neural network against its degradation counterparts. This design allows for the SRR tailored to an individual subject, as the training requires the scan-specific data only, i.e., it does not require auxiliary datasets of high-quality images, which are practically challenging to obtain. With this technique, we achieved high-quality brain MRI at an isotropic resolution of 0.125 cubic mm with six minutes of imaging time. Extensive experiments on both simulated low-resolution data and clinical data acquired from ten pediatric patients demonstrated that our approach achieved superior SRR results as compared to state-of-the-art deconvolution-based methods, while in parallel, at substantially reduced imaging time in comparison to direct high-resolution acquisitions. |
| Author | Gholipour, Ali Warfield, Simon K. Afacan, Onur Sui, Yao |
| Author_xml | – sequence: 1 givenname: Yao surname: Sui fullname: Sui, Yao email: yao.sui@childrens.harvard.edu – sequence: 2 givenname: Onur surname: Afacan fullname: Afacan, Onur – sequence: 3 givenname: Ali surname: Gholipour fullname: Gholipour, Ali – sequence: 4 givenname: Simon K. surname: Warfield fullname: Warfield, Simon K. |
| BackLink | https://www.ncbi.nlm.nih.gov/pubmed/34713277$$D View this record in MEDLINE/PubMed |
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| Copyright | Springer Nature Switzerland AG 2021 |
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| DOI | 10.1007/978-3-030-87231-1_42 |
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| Discipline | Medicine Applied Sciences Computer Science |
| EISBN | 3030872319 9783030872311 |
| EISSN | 1611-3349 |
| Editor | Cotin, Stéphane Essert, Caroline de Bruijne, Marleen Cattin, Philippe C Speidel, Stefanie Padoy, Nicolas Zheng, Yefeng |
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| Keywords | Deep learning MRI Super-resolution |
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| Notes | Electronic supplementary materialThe online version of this chapter (https://doi.org/10.1007/978-3-030-87231-1_42) contains supplementary material, which is available to authorized users. This work was supported in part by the National Institutes of Health (NIH) under grants R01 NS079788, R01 EB019483, R01 EB018988, R01 NS106030, R01 EB031849, IDDRC U54 HD090255, S10OD025111; a research grant from the Boston Children’s Hospital Translational Research Program; a Technological Innovations in Neuroscience Award from the McKnight Foundation; a research grant from the Thrasher Research Fund; and a pilot grant from National Multiple Sclerosis Society under Award Number PP-1905-34002. |
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| PublicationSubtitle | 24th International Conference, Strasbourg, France, September 27-October 1, 2021, Proceedings, Part VI |
| PublicationTitle | Medical Image Computing and Computer Assisted Intervention - MICCAI 2021 |
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| RelatedPersons | Hartmanis, Juris Gao, Wen Bertino, Elisa Woeginger, Gerhard Goos, Gerhard Steffen, Bernhard Yung, Moti |
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| SubjectTerms | Deep learning MRI Super-resolution |
| Title | MRI Super-Resolution Through Generative Degradation Learning |
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