PURPOSE: To obtain diffusion tensor images (DTI) over a large image volume rapidly with 3D isotropic spatial resolution, minimal spatial distortions, and reduced motion artifacts, a diffusion-weighted steady-state 3D projection (SS 3DPR) pulse sequence was developed. MATERIALS AND METHODS: A diffusion gradient was inserted in a SS 3DPR pulse sequence. The acquisition was synchronized to the cardiac cycle, linear phase errors were corrected along the readout direction, and each projection was weighted by measures of consistency with other data. A new iterative parallel imaging reconstruction method was also implemented for removing off-resonance and undersampling artifacts simultaneously. RESULTS: The contrast and appearance of both the fractional anisotropy and eigenvector color maps were substantially improved after all correction techniques were applied. True 3D DTI datasets were obtained in vivo over the whole brain (240 mm field of view in all directions) with 1.87 mm isotropic spatial resolution, six diffusion encoding directions in under 19 minutes. CONCLUSION: A true 3D DTI pulse sequence with high isotropic spatial resolution was developed for whole brain imaging in under 20 minutes. To minimize the effects of brain motion, a cardiac synchronized, multiecho, DW-SSFP pulse sequence was implemented. Motion artifacts were further reduced by a combination of linear phase correction, corrupt projection detection and rejection, sampling density reweighting, and parallel imaging reconstruction. The combination of these methods greatly improved the quality of 3D DTI in the brain.
PURPOSE: To obtain diffusion tensor images (DTI) over a large image volume rapidly with 3D isotropic spatial resolution, minimal spatial distortions, and reduced motion artifacts, a diffusion-weighted steady-state 3D projection (SS 3DPR) pulse sequence was developed. MATERIALS AND METHODS: A diffusion gradient was inserted in a SS 3DPR pulse sequence. The acquisition was synchronized to the cardiac cycle, linear phase errors were corrected along the readout direction, and each projection was weighted by measures of consistency with other data. A new iterative parallel imaging reconstruction method was also implemented for removing off-resonance and undersampling artifacts simultaneously. RESULTS: The contrast and appearance of both the fractional anisotropy and eigenvector color maps were substantially improved after all correction techniques were applied. True 3D DTI datasets were obtained in vivo over the whole brain (240 mm field of view in all directions) with 1.87 mm isotropic spatial resolution, six diffusion encoding directions in under 19 minutes. CONCLUSION: A true 3D DTI pulse sequence with high isotropic spatial resolution was developed for whole brain imaging in under 20 minutes. To minimize the effects of brain motion, a cardiac synchronized, multiecho, DW-SSFP pulse sequence was implemented. Motion artifacts were further reduced by a combination of linear phase correction, corrupt projection detection and rejection, sampling density reweighting, and parallel imaging reconstruction. The combination of these methods greatly improved the quality of 3D DTI in the brain.
Authors: Sandeep N Gupta; Meiyappan Solaiyappan; Garth M Beache; Andrew E Arai; Thomas K F Foo Journal: Magn Reson Med Date: 2003-03 Impact factor: 4.668
Authors: Mariana Lazar; David M Weinstein; Jay S Tsuruda; Khader M Hasan; Konstantinos Arfanakis; M Elizabeth Meyerand; Benham Badie; Howard A Rowley; Victor Haughton; Aaron Field; Andrew L Alexander Journal: Hum Brain Mapp Date: 2003-04 Impact factor: 5.038
Authors: Alexey A Samsonov; Julia Velikina; Youngkyoo Jung; Eugene G Kholmovski; Chris R Johnson; Walter F Block Journal: Magn Reson Med Date: 2010-04 Impact factor: 4.668
Authors: Rafael O'Halloran; Murat Aksoy; Eric Aboussouan; Eric Peterson; Anh Van; Roland Bammer Journal: Magn Reson Med Date: 2014-04-08 Impact factor: 4.668