PURPOSE: To develop and translate a metabolite-specific imaging sequence using a symmetric echo planar readout for clinical hyperpolarized (HP) Carbon-13 (13 C) applications. METHODS: Initial data were acquired from patients with prostate cancer (N = 3) and high-grade brain tumors (N = 3) on a 3T scanner. Samples of [1-13 C]pyruvate were polarized for at least 2 h using a 5T SPINlab system operating at 0.8 K. Following injection of the HP substrate, pyruvate, lactate, and bicarbonate (for brain studies) were sequentially excited with a singleband spectral-spatial RF pulse and signal was rapidly encoded with a single-shot echo planar readout on a slice-by-slice basis. Data were acquired dynamically with a temporal resolution of 2 s for prostate studies and 3 s for brain studies. RESULTS: High pyruvate signal was seen throughout the prostate and brain, with conversion to lactate being shown across studies, whereas bicarbonate production was also detected in the brain. No Nyquist ghost artifacts or obvious geometric distortion from the echo planar readout were observed. The average error in center frequency was 1.2 ± 17.0 and 4.5 ± 1.4 Hz for prostate and brain studies, respectively, below the threshold for spatial shift because of bulk off-resonance. CONCLUSION: This study demonstrated the feasibility of symmetric EPI to acquire HP 13 C metabolite maps in a clinical setting. As an advance over prior single-slice dynamic or single time point volumetric spectroscopic imaging approaches, this metabolite-specific EPI acquisition provided robust whole-organ coverage for brain and prostate studies while retaining high SNR, spatial resolution, and dynamic temporal resolution.
PURPOSE: To develop and translate a metabolite-specific imaging sequence using a symmetric echo planar readout for clinical hyperpolarized (HP) Carbon-13 (13 C) applications. METHODS: Initial data were acquired from patients with prostate cancer (N = 3) and high-grade brain tumors (N = 3) on a 3T scanner. Samples of [1-13 C]pyruvate were polarized for at least 2 h using a 5T SPINlab system operating at 0.8 K. Following injection of the HP substrate, pyruvate, lactate, and bicarbonate (for brain studies) were sequentially excited with a singleband spectral-spatial RF pulse and signal was rapidly encoded with a single-shot echo planar readout on a slice-by-slice basis. Data were acquired dynamically with a temporal resolution of 2 s for prostate studies and 3 s for brain studies. RESULTS: High pyruvate signal was seen throughout the prostate and brain, with conversion to lactate being shown across studies, whereas bicarbonate production was also detected in the brain. No Nyquist ghost artifacts or obvious geometric distortion from the echo planar readout were observed. The average error in center frequency was 1.2 ± 17.0 and 4.5 ± 1.4 Hz for prostate and brain studies, respectively, below the threshold for spatial shift because of bulk off-resonance. CONCLUSION: This study demonstrated the feasibility of symmetric EPI to acquire HP 13 C metabolite maps in a clinical setting. As an advance over prior single-slice dynamic or single time point volumetric spectroscopic imaging approaches, this metabolite-specific EPI acquisition provided robust whole-organ coverage for brain and prostate studies while retaining high SNR, spatial resolution, and dynamic temporal resolution.
Authors: Charles H Cunningham; Albert P Chen; Michael Lustig; Brian A Hargreaves; Janine Lupo; Duan Xu; John Kurhanewicz; Ralph E Hurd; John M Pauly; Sarah J Nelson; Daniel B Vigneron Journal: J Magn Reson Date: 2008-03-23 Impact factor: 2.229
Authors: Angus Z Lau; Albert P Chen; Nilesh R Ghugre; Venkat Ramanan; Wilfred W Lam; Kim A Connelly; Graham A Wright; Charles H Cunningham Journal: Magn Reson Med Date: 2010-11 Impact factor: 4.668
Authors: Ilwoo Park; Peder E Z Larson; Jeremy W Gordon; Lucas Carvajal; Hsin-Yu Chen; Robert Bok; Mark Van Criekinge; Marcus Ferrone; James B Slater; Duan Xu; John Kurhanewicz; Daniel B Vigneron; Susan Chang; Sarah J Nelson Journal: Magn Reson Med Date: 2018-01-10 Impact factor: 4.668
Authors: Jan H Ardenkjaer-Larsen; Björn Fridlund; Andreas Gram; Georg Hansson; Lennart Hansson; Mathilde H Lerche; Rolf Servin; Mikkel Thaning; Klaes Golman Journal: Proc Natl Acad Sci U S A Date: 2003-08-20 Impact factor: 11.205
Authors: Daniele Mammoli; Jeremy Gordon; Adam Autry; Peder E Z Larson; Yan Li; Hsin-Yu Chen; Brian Chung; Peter Shin; Mark Van Criekinge; Lucas Carvajal; James B Slater; Robert Bok; Jason Crane; Duan Xu; Susan Chang; Daniel B Vigneron Journal: IEEE Trans Med Imaging Date: 2019-07-02 Impact factor: 10.048
Authors: Eugene Milshteyn; Galen D Reed; Jeremy W Gordon; Cornelius von Morze; Peng Cao; Shuyu Tang; Andrew P Leynes; Peder E Z Larson; Daniel B Vigneron Journal: J Magn Reson Date: 2020-02-01 Impact factor: 2.229
Authors: Collin J Harlan; Zhan Xu; Keith A Michel; Christopher M Walker; Sanjaya D Lokugama; Gary V Martinez; Mark D Pagel; James A Bankson Journal: Med Phys Date: 2020-05-11 Impact factor: 4.071
Authors: Jeremy W Gordon; Adam W Autry; Shuyu Tang; Jasmine Y Graham; Robert A Bok; Xucheng Zhu; Javier E Villanueva-Meyer; Yan Li; Michael A Ohilger; Maria Roselle Abraham; Duan Xu; Daniel B Vigneron; Peder E Z Larson Journal: Magn Reson Med Date: 2020-07-22 Impact factor: 4.668
Authors: Shuyu Tang; Robert Bok; Hecong Qin; Galen Reed; Mark VanCriekinge; Romelyn Delos Santos; William Overall; Juan Santos; Jeremy Gordon; Zhen Jane Wang; Daniel B Vigneron; Peder E Z Larson Journal: Magn Reson Med Date: 2020-02-21 Impact factor: 4.668
Authors: Nikolaj Bøgh; Rie B Olin; Esben Ss Hansen; Jeremy W Gordon; Sabrina K Bech; Lotte B Bertelsen; Juan D Sánchez-Heredia; Jakob U Blicher; Leif Østergaard; Jan H Ardenkjær-Larsen; Robert A Bok; Daniel B Vigneron; Christoffer Laustsen Journal: J Cereb Blood Flow Metab Date: 2021-05-20 Impact factor: 6.200
Authors: Jason C Crane; Jeremy W Gordon; Hsin-Yu Chen; Adam W Autry; Yan Li; Marram P Olson; John Kurhanewicz; Daniel B Vigneron; Peder E Z Larson; Duan Xu Journal: NMR Biomed Date: 2020-03-19 Impact factor: 4.044