PURPOSE: To investigate the effect of the asymmetric gradient concomitant fields (CF) with zeroth and first-order spatial dependence on fast/turbo spin-echo acquisitions, and to demonstrate the effectiveness of their real-time compensation. METHODS: After briefly reviewing the CF produced by asymmetric gradients, the effects of the additional zeroth and first-order CFs on these systems are investigated using extended-phase graph simulations. Phantom and in vivo experiments are performed to corroborate the simulation. Experiments are performed before and after the real-time compensations using frequency tracking and gradient pre-emphasis to demonstrate their effectiveness in correcting the additional CFs. The interaction between the CFs and prescan-based correction to compensate for eddy currents is also investigated. RESULTS: It is demonstrated that, unlike the second-order CFs on conventional gradients, the additional zeroth/first-order CFs on asymmetric gradients cause substantial signal loss and dark banding in fast spin-echo acquisitions within a typical brain-scan field of view. They can confound the prescan correction for eddy currents and degrade image quality. Performing real-time compensation successfully eliminates the artifacts. CONCLUSIONS: We demonstrate that the zeroth/first-order CFs specific to asymmetric gradients can cause substantial artifacts, including signal loss and dark bands for brain imaging. These effects can be corrected using real-time compensation. Magn Reson Med 79:1354-1364, 2018.
PURPOSE: To investigate the effect of the asymmetric gradient concomitant fields (CF) with zeroth and first-order spatial dependence on fast/turbo spin-echo acquisitions, and to demonstrate the effectiveness of their real-time compensation. METHODS: After briefly reviewing the CF produced by asymmetric gradients, the effects of the additional zeroth and first-order CFs on these systems are investigated using extended-phase graph simulations. Phantom and in vivo experiments are performed to corroborate the simulation. Experiments are performed before and after the real-time compensations using frequency tracking and gradient pre-emphasis to demonstrate their effectiveness in correcting the additional CFs. The interaction between the CFs and prescan-based correction to compensate for eddy currents is also investigated. RESULTS: It is demonstrated that, unlike the second-order CFs on conventional gradients, the additional zeroth/first-order CFs on asymmetric gradients cause substantial signal loss and dark banding in fast spin-echo acquisitions within a typical brain-scan field of view. They can confound the prescan correction for eddy currents and degrade image quality. Performing real-time compensation successfully eliminates the artifacts. CONCLUSIONS: We demonstrate that the zeroth/first-order CFs specific to asymmetric gradients can cause substantial artifacts, including signal loss and dark bands for brain imaging. These effects can be corrected using real-time compensation. Magn Reson Med 79:1354-1364, 2018.
Authors: Shengzhen Tao; Joshua D Trzasko; Yunhong Shu; Paul T Weavers; John Huston; Erin M Gray; Matt A Bernstein Journal: Magn Reson Med Date: 2015-07-17 Impact factor: 4.668
Authors: Ek T Tan; Seung-Kyun Lee; Paul T Weavers; Dominic Graziani; Joseph E Piel; Yunhong Shu; John Huston; Matt A Bernstein; Thomas K F Foo Journal: J Magn Reson Imaging Date: 2016-02-26 Impact factor: 4.813
Authors: Seung-Kyun Lee; Jean-Baptiste Mathieu; Dominic Graziani; Joseph Piel; Eric Budesheim; Eric Fiveland; Christopher J Hardy; Ek Tsoon Tan; Bruce Amm; Thomas K-F Foo; Matt A Bernstein; John Huston; Yunhong Shu; John F Schenck Journal: Magn Reson Med Date: 2015-12-02 Impact factor: 4.668
Authors: Paul T Weavers; Shengzhen Tao; Joshua D Trzasko; Louis M Frigo; Yunhong Shu; Matthew A Frick; Seung-Kyun Lee; Thomas K-F Foo; Matt A Bernstein Journal: Magn Reson Med Date: 2017-06-21 Impact factor: 4.668
Authors: Thomas K F Foo; Evangelos Laskaris; Mark Vermilyea; Minfeng Xu; Paul Thompson; Gene Conte; Christopher Van Epps; Christopher Immer; Seung-Kyun Lee; Ek T Tan; Dominic Graziani; Jean-Baptise Mathieu; Christopher J Hardy; John F Schenck; Eric Fiveland; Wolfgang Stautner; Justin Ricci; Joseph Piel; Keith Park; Yihe Hua; Ye Bai; Alex Kagan; David Stanley; Paul T Weavers; Erin Gray; Yunhong Shu; Matthew A Frick; Norbert G Campeau; Joshua Trzasko; John Huston; Matt A Bernstein Journal: Magn Reson Med Date: 2018-03-13 Impact factor: 4.668