TY - GEN
T1 - Toward effective noise reduction for sub-Nyquist high-frame-rate MRI techniques with deep learning
AU - Suzuki, Yudai
AU - Kawaji, Keigo
AU - Patel, Amit R.
AU - Tamura, Satoshi
AU - Hayamizu, Satoru
N1 - Publisher Copyright:
© 2017 IEEE.
PY - 2018/2/5
Y1 - 2018/2/5
N2 - Cine Cardiac Magnetic Resonance (Cine-CMR) is one example of dynamic MRI approaches to image organs that exhibit periodic motion. Conventional routine clinical Cine-CMR are typically obtained at 20-35 frames per second (fps) with temporal window sizes of 40-50 milliseconds. We have recently shown the feasibility of significantly increasing this overall frame rate by an acquisition of MRI k-space using a highly optimized radial sampling pattern with respect to both spatial and temporal coverage. In brief, our proposed approach acquires a significantly undersampled radial MRI k-space while encoding spatially and temporally periodic noise characteristics through the undersampled radial MRI acquisition; however, remnant radial streaking noise remain under physiologic imaging conditions. In this research, we propose to further remove these streaking noise, employing a Spatio-Temporal Denoising Auto-Encoder (ST-DAE) based on deep learning. We evaluate performance of our method in addressing such remnant artifact using ST-DAE; PSNR is used to evaluate image quality, and computational time is also discussed.
AB - Cine Cardiac Magnetic Resonance (Cine-CMR) is one example of dynamic MRI approaches to image organs that exhibit periodic motion. Conventional routine clinical Cine-CMR are typically obtained at 20-35 frames per second (fps) with temporal window sizes of 40-50 milliseconds. We have recently shown the feasibility of significantly increasing this overall frame rate by an acquisition of MRI k-space using a highly optimized radial sampling pattern with respect to both spatial and temporal coverage. In brief, our proposed approach acquires a significantly undersampled radial MRI k-space while encoding spatially and temporally periodic noise characteristics through the undersampled radial MRI acquisition; however, remnant radial streaking noise remain under physiologic imaging conditions. In this research, we propose to further remove these streaking noise, employing a Spatio-Temporal Denoising Auto-Encoder (ST-DAE) based on deep learning. We evaluate performance of our method in addressing such remnant artifact using ST-DAE; PSNR is used to evaluate image quality, and computational time is also discussed.
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U2 - 10.1109/APSIPA.2017.8282197
DO - 10.1109/APSIPA.2017.8282197
M3 - Conference contribution
AN - SCOPUS:85050530915
T3 - Proceedings - 9th Asia-Pacific Signal and Information Processing Association Annual Summit and Conference, APSIPA ASC 2017
SP - 1136
EP - 1139
BT - Proceedings - 9th Asia-Pacific Signal and Information Processing Association Annual Summit and Conference, APSIPA ASC 2017
PB - Institute of Electrical and Electronics Engineers Inc.
T2 - 9th Asia-Pacific Signal and Information Processing Association Annual Summit and Conference, APSIPA ASC 2017
Y2 - 12 December 2017 through 15 December 2017
ER -