Justin P Haldar1, Yunsong Liu1, Congyu Liao2, Qiuyun Fan2, Kawin Setsompop2. 1. Ming Hsieh Department of Electrical and Computer Engineering, University of Southern California, Los Angeles, CA, USA. 2. Athinoula A. Martinos Center for Biomedical Imaging, Charlestown, MA, USA.
Abstract
PURPOSE: We evaluate a new approach for achieving diffusion MRI data with high spatial resolution, large volume coverage, and fast acquisition speed. THEORY AND METHODS: A recent method called gSlider-SMS enables whole-brain submillimeter diffusion MRI with high signal-to-noise ratio (SNR) efficiency. However, despite the efficient acquisition, the resulting images can still suffer from low SNR due to the small size of the imaging voxels. This work proposes to mitigate the SNR problem by combining gSlider-SMS with a regularized SNR-enhancing reconstruction approach. RESULTS: Illustrative results show that, from gSlider-SMS data acquired over a span of only 25 minutes on a 3T scanner, the proposed method is able to produce 71 MRI images (64 diffusion encoding orientations with b = 1500 s/ mm 2 , and 7 images without diffusion weighting) of the entire in vivo human brain with nominal 0.66 mm spatial resolution. Using data acquired from 75 minutes of acquisition as a gold standard reference, we demonstrate that the proposed SNR-enhancement procedure leads to substantial improvements in estimated diffusion parameters compared to conventional gSlider reconstruction. Results also demonstrate that the proposed method has advantages relative to denoising methods based on low-rank matrix modeling. A theoretical analysis of the trade-off between spatial resolution and SNR suggests that the proposed approach has high efficiency. CONCLUSIONS: The combination of gSlider-SMS with advanced regularized reconstruction enables high-resolution quantitative diffusion MRI from a relatively fast acquisition.
PURPOSE: We evaluate a new approach for achieving diffusion MRI data with high spatial resolution, large volume coverage, and fast acquisition speed. THEORY AND METHODS: A recent method called gSlider-SMS enables whole-brain submillimeter diffusion MRI with high signal-to-noise ratio (SNR) efficiency. However, despite the efficient acquisition, the resulting images can still suffer from low SNR due to the small size of the imaging voxels. This work proposes to mitigate the SNR problem by combining gSlider-SMS with a regularized SNR-enhancing reconstruction approach. RESULTS: Illustrative results show that, from gSlider-SMS data acquired over a span of only 25 minutes on a 3T scanner, the proposed method is able to produce 71 MRI images (64 diffusion encoding orientations with b = 1500 s/ mm 2 , and 7 images without diffusion weighting) of the entire in vivo human brain with nominal 0.66 mm spatial resolution. Using data acquired from 75 minutes of acquisition as a gold standard reference, we demonstrate that the proposed SNR-enhancement procedure leads to substantial improvements in estimated diffusion parameters compared to conventional gSlider reconstruction. Results also demonstrate that the proposed method has advantages relative to denoising methods based on low-rank matrix modeling. A theoretical analysis of the trade-off between spatial resolution and SNR suggests that the proposed approach has high efficiency. CONCLUSIONS: The combination of gSlider-SMS with advanced regularized reconstruction enables high-resolution quantitative diffusion MRI from a relatively fast acquisition.
Authors: Robin M Heidemann; Alfred Anwander; Thorsten Feiweier; Thomas R Knösche; Robert Turner Journal: Neuroimage Date: 2012-01-09 Impact factor: 6.556
Authors: Sen Ma; Christopher T Nguyen; Anthony G Christodoulou; Daniel Luthringer; Jon Kobashigawa; Sang-Eun Lee; Hyuk-Jae Chang; Debiao Li Journal: IEEE Trans Biomed Eng Date: 2017-12-25 Impact factor: 4.538
Authors: Fuyixue Wang; Zijing Dong; Qiyuan Tian; Congyu Liao; Qiuyun Fan; W Scott Hoge; Boris Keil; Jonathan R Polimeni; Lawrence L Wald; Susie Y Huang; Kawin Setsompop Journal: Sci Data Date: 2021-04-29 Impact factor: 6.444