2022
DOI: 10.1002/mp.15636
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Deep learning‐based 3D MRI contrast‐enhanced synthesis from a 2D noncontrast T2Flair sequence

Abstract: Purpose Gadolinium‐based contrast agents (GBCAs) have been successfully applied in magnetic resonance (MR) imaging to facilitate better lesion visualization. However, gadolinium deposition in the human brain raised widespread concerns recently. On the other hand, although high‐resolution three‐dimensional (3D) MR images are more desired for most existing medical image processing algorithms, their long scan duration and high acquiring costs make 2D MR images still much more common clinically. Therefore, develop… Show more

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Cited by 14 publications
(19 citation statements)
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“…The whole-brain peak signal-tonoise ratio was 32.25 dB (in tumor regions, it was 24.93 dB), structural similarity index measure was 0.932 (tumor regions, 0.851), and AUC was 0.991 (tumor regions, 0.929). 38 As a result, this method was found to be potentially useful in synthesizing 3D isotropic contrast-enhanced brain MR images from a single 2D anisotropic noncontrast sequence. Because this study was intended to evaluate the use of precontrast 2D T2 FLAIR images to predict 3D postcontrast T2 FLAIR images, the research focused on superresolution imaging rather than contrast synthesis, which is typically evaluated using T1-weighted images.…”
Section: Gbca-free Brain Mrimentioning
confidence: 99%
See 2 more Smart Citations
“…The whole-brain peak signal-tonoise ratio was 32.25 dB (in tumor regions, it was 24.93 dB), structural similarity index measure was 0.932 (tumor regions, 0.851), and AUC was 0.991 (tumor regions, 0.929). 38 As a result, this method was found to be potentially useful in synthesizing 3D isotropic contrast-enhanced brain MR images from a single 2D anisotropic noncontrast sequence. Because this study was intended to evaluate the use of precontrast 2D T2 FLAIR images to predict 3D postcontrast T2 FLAIR images, the research focused on superresolution imaging rather than contrast synthesis, which is typically evaluated using T1-weighted images.…”
Section: Gbca-free Brain Mrimentioning
confidence: 99%
“…34 Finally, another research group was motivated to find a solution to synthesizing and replacing 3D contrast-enhanced MR images, given the long scan duration and relatively high acquisition costs of these 3D sequences. 38 A DL-based model was used to obtain 3D isotropic full-dose postcontrast T2-weighted FLAIR images from 2D anisotropic noncontrast T2-weighted FLAIR images. An identical generative adversarial network was used to perform superresolution and synthesize contrast-enhanced characteristics.…”
Section: Gbca-free Brain Mrimentioning
confidence: 99%
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“…Faster R-CNN uses another convolutional net-work (RPN) to extract candidate frames, applies a convolutional network to the entire image to obtain feature maps, and passes feature maps into RPN networks to extract candidate boxes [10][11][12]. This chapter considers the use of encryption algorithms of different strengths and different convolutional network structures for datasets, and analyzes whether the encrypted image leaks the information of the original image [13][14][15][16]. By using the encrypted image as the training set of the convolutional network, in which the label of each image is unchanged, if the judgment accuracy of the convolutional network in the test set is higher than the random prediction effect, it indicates that the convolutional network has learned some commonalities in the encryption process and analyzed the encryption mode.…”
Section: Introductionmentioning
confidence: 99%
“…MRI synthesis approaches based on deep learning currently serve as an emerging field of research in neuro-oncology. 8,9 In particular, various deep learning-based approaches have been investigated for contrast-enhanced MRI synthesis toward reduction 7,[10][11][12][13] or even elimination 8,[14][15][16][17][18][19][20][21][22] of gadolinium contrast agents in glioma patients. The former involves methods that propose the synthesis of full-dose contrast-enhanced images from their low-dose counterparts (e.g., 10% low-dose).…”
Section: Introductionmentioning
confidence: 99%