PURPOSE: To evaluate the feasibility of applying the shells trajectory to single-phase contrast-enhanced magnetic resonance angiography. MATERIALS AND METHOD: Several methods were developed to overcome the challenges of the clinical implementation of shells including off-resonance blurring (eg, from lipid signal), aliasing artifacts, and long reconstruction times. These methods included: 1) variable TR with variable readout length to reduce fat signal and off-resonance blurring; 2) variable sampling density to suppress aliasing artifacts while minimizing acquisition time penalty; and 3) an online 3D gridding algorithm that reconstructed an 8-channel, 240(3) image volume set. Both phantom and human studies were performed to establish the initial feasibility of the methods. RESULTS: Phantom and human study results demonstrated the effectiveness of the proposed methods. Shells with variable TR and readout length further suppressed the fat signal compared to the fixed-TR shells acquisition. Reduced image aliasing was achieved with minimal scan time penalty when a variable sampling density technique was used. The fast online reconstruction algorithm completed in 2 minutes at the scanner console, providing a timely image display in a clinical setting. CONCLUSION: It was demonstrated that the use of the shells trajectory is feasible in a clinical setting to acquire intracranial angiograms with high spatial resolution. Preliminary results demonstrate effective venous suppression in the cavernous sinuses and jugular vein region.
PURPOSE: To evaluate the feasibility of applying the shells trajectory to single-phase contrast-enhanced magnetic resonance angiography. MATERIALS AND METHOD: Several methods were developed to overcome the challenges of the clinical implementation of shells including off-resonance blurring (eg, from lipid signal), aliasing artifacts, and long reconstruction times. These methods included: 1) variable TR with variable readout length to reduce fat signal and off-resonance blurring; 2) variable sampling density to suppress aliasing artifacts while minimizing acquisition time penalty; and 3) an online 3D gridding algorithm that reconstructed an 8-channel, 240(3) image volume set. Both phantom and human studies were performed to establish the initial feasibility of the methods. RESULTS: Phantom and human study results demonstrated the effectiveness of the proposed methods. Shells with variable TR and readout length further suppressed the fat signal compared to the fixed-TR shells acquisition. Reduced image aliasing was achieved with minimal scan time penalty when a variable sampling density technique was used. The fast online reconstruction algorithm completed in 2 minutes at the scanner console, providing a timely image display in a clinical setting. CONCLUSION: It was demonstrated that the use of the shells trajectory is feasible in a clinical setting to acquire intracranial angiograms with high spatial resolution. Preliminary results demonstrate effective venous suppression in the cavernous sinuses and jugular vein region.
Authors: Shengzhen Tao; Joshua D Trzasko; Yunhong Shu; John Huston; Kevin M Johnson; Paul T Weavers; Erin M Gray; Matt A Bernstein Journal: Med Phys Date: 2015-12 Impact factor: 4.071
Authors: Yunhong Shu; Shengzhen Tao; Joshua D Trzasko; John Huston; Paul T Weavers; Matt A Bernstein Journal: Magn Reson Med Date: 2017-08-21 Impact factor: 4.668
Authors: Shengzhen Tao; Paul T Weavers; Joshua D Trzasko; Yunhong Shu; John Huston; Seung-Kyun Lee; Louis M Frigo; Matt A Bernstein Journal: Magn Reson Med Date: 2016-07-04 Impact factor: 4.668