Deep Learning-based Noise Reduction for Fast Volume Diffusion Tensor Imaging: Assessing the Noise Reduction Effect and Reliability of Diffusion Metrics

Deep Learning-based Noise Reduction for Fast Volume Diffusion Tensor Imaging: Assessing the Noise Reduction Effect and Reliability of Diffusion Metrics

To assess the feasibility of a denoising approach with deep learning-based reconstruction (dDLR) for fast volume simultaneous multi-slice diffusion tensor imaging of the brain, noise reduction effects and the reliability of diffusion metrics were evaluated with 20 patients. Image noise was significa...

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Veröffentlicht in:Magnetic Resonance in Medical Sciences 2021, Vol.20(4), pp.450-456
Hauptverfasser: Sagawa, Hajime, Fushimi, Yasutaka, Nakajima, Satoshi, Fujimoto, Koji, Miyake, Kanae Kawai, Numamoto, Hitomi, Koizumi, Koji, Nambu, Masahito, Kataoka, Hiroharu, Nakamoto, Yuji, Saga, Tsuneo
Format: Artikel
Sprache:eng
Schlagworte:
Anisotropy
Benchmarking
Brain slice preparation
Deep Learning
denoising approach with deep learning-based reconstruction
Diffusion effects
Diffusion rate
Diffusion Tensor Imaging
diffusion tensor tractography
Humans
Image acquisition
Image Processing, Computer-Assisted
Image reconstruction
Magnetic resonance imaging
Mathematical analysis
Medical imaging
Neuroimaging
Noise control
Noise reduction
number of image acquisition
Reliability analysis
Reproducibility of Results
Substantia grisea
Technical Note
Tensors
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Zusammenfassung:To assess the feasibility of a denoising approach with deep learning-based reconstruction (dDLR) for fast volume simultaneous multi-slice diffusion tensor imaging of the brain, noise reduction effects and the reliability of diffusion metrics were evaluated with 20 patients. Image noise was significantly decreased with dDLR. Although fractional anisotropy (FA) of deep gray matter was overestimated when the number of image acquisitions was one (NAQ1), FA in NAQ1 with dDLR became closer to that in NAQ5.
ISSN:1347-3182
1880-2206
DOI:10.2463/mrms.tn.2020-0061