PURPOSE: Chemical exchange sensitive spin-lock and related techniques allow to observe the uptake of administered D-glucose in vivo. The exchange-weighting increases with the magnetic field strength, but inhomogeneities in the radiofrequency (RF) field at ultrahigh field whole-body scanners lead to artifacts in conventional spin-lock experiments. Thus, our aim was the development of an adiabatically prepared T1ρ -based imaging sequence applicable to studies of glucose metabolism in tumor patients at ultrahigh field strengths. METHODS: An adiabatically prepared on-resonant spin-lock approach was realized at a 7 Tesla whole-body scanner and compared with conventional spin-lock. The insensitivity to RF field inhomogeneities as well as the chemical exchange sensitivity of the approach was investigated in simulations, model solutions and in the human brain. RESULTS: The suggested spin-lock approach was shown to be feasible for in vivo application at ultrahigh field whole-body scanners and showed substantially improved image quality compared with conventional spin-lock. The sensitivity of the presented method to glucose was verified in model solutions and a glucose contrast was observed in a glioblastoma patient after intravenous administration of glucose solution. CONCLUSION: An adiabatically prepared spin-lock preparation was presented that enables a homogeneous and chemical exchange sensitive T1ρ -based imaging at ultra-high field whole-body scanners, e.g., for T1ρ -based dynamic glucose enhanced MRI. Magn Reson Med 78:215-225, 2017.
PURPOSE: Chemical exchange sensitive spin-lock and related techniques allow to observe the uptake of administered D-glucose in vivo. The exchange-weighting increases with the magnetic field strength, but inhomogeneities in the radiofrequency (RF) field at ultrahigh field whole-body scanners lead to artifacts in conventional spin-lock experiments. Thus, our aim was the development of an adiabatically prepared T1ρ -based imaging sequence applicable to studies of glucose metabolism in tumorpatients at ultrahigh field strengths. METHODS: An adiabatically prepared on-resonant spin-lock approach was realized at a 7 Tesla whole-body scanner and compared with conventional spin-lock. The insensitivity to RF field inhomogeneities as well as the chemical exchange sensitivity of the approach was investigated in simulations, model solutions and in the human brain. RESULTS: The suggested spin-lock approach was shown to be feasible for in vivo application at ultrahigh field whole-body scanners and showed substantially improved image quality compared with conventional spin-lock. The sensitivity of the presented method to glucose was verified in model solutions and a glucose contrast was observed in a glioblastomapatient after intravenous administration of glucose solution. CONCLUSION: An adiabatically prepared spin-lock preparation was presented that enables a homogeneous and chemical exchange sensitive T1ρ -based imaging at ultra-high field whole-body scanners, e.g., for T1ρ -based dynamic glucose enhanced MRI. Magn Reson Med 78:215-225, 2017.
Authors: Robert J Harris; Jingwen Yao; Ararat Chakhoyan; Catalina Raymond; Kevin Leu; Linda M Liau; Phioanh L Nghiemphu; Albert Lai; Noriko Salamon; Whitney B Pope; Timothy F Cloughesy; Benjamin M Ellingson Journal: Magn Reson Med Date: 2018-04-06 Impact factor: 4.668
Authors: Xiang Xu; Akansha Ashvani Sehgal; Nirbhay N Yadav; John Laterra; Lindsay Blair; Jaishri Blakeley; Anina Seidemo; Jennifer M Coughlin; Martin G Pomper; Linda Knutsson; Peter C M van Zijl Journal: Magn Reson Med Date: 2019-12-24 Impact factor: 4.668
Authors: Xiang Xu; Jiadi Xu; Kannie W Y Chan; Jing Liu; Huanling Liu; Yuguo Li; Lin Chen; Guanshu Liu; Peter C M van Zijl Journal: Magn Reson Med Date: 2018-07-29 Impact factor: 4.668
Authors: Ouri Cohen; Shuning Huang; Michael T McMahon; Matthew S Rosen; Christian T Farrar Journal: Magn Reson Med Date: 2018-05-13 Impact factor: 4.668
Authors: Nana Owusu; Casey P Johnson; William Kearney; Dan Thedens; John Wemmie; Vincent A Magnotta Journal: NMR Biomed Date: 2019-11-19 Impact factor: 4.044