PURPOSE: To optimize the Rosette trajectories for fast, high sensitivity spectroscopic imaging experiments and to compare this acquisition technique with other chemical shift imaging (CSI) methods. MATERIALS AND METHODS: A framework for comparing the sensitivity of the Rosette Spectroscopic Imaging (RSI) acquisition to other spectroscopic imaging experiments is outlined. Accounting for hardware constraints, trajectory parameters that provide for optimal sampling and minimal artifact production are found. Along with an analytical expression for the number of excitations to be used in an RSI experiment that is provided, the theoretical precompensation weights used for optimal image reconstruction are derived. RESULTS: The spectral response function for RSI is shown to be approximately the same as the point spread function of standard Fourier reconstructions. While the signal-to-noise ratio (SNR) for an RSI experiment is reduced by the inherent nonuniform sampling of these trajectories, their circular k-space support and speed of spatial encoding leads to greater SNR efficiency and improvements in the total data acquisition time relative to the gold standard CSI approach with square k-space support and to similar efficiency to spiral CSI acquisitions. Numerical simulations and in vivo experimental data are presented to demonstrate the properties of this data acquisition technique. CONCLUSION: This work demonstrates the use of Rosette trajectories and how to achieve improved efficiency for these trajectories in a two-dimensional spectroscopic imaging experiment.
PURPOSE: To optimize the Rosette trajectories for fast, high sensitivity spectroscopic imaging experiments and to compare this acquisition technique with other chemical shift imaging (CSI) methods. MATERIALS AND METHODS: A framework for comparing the sensitivity of the Rosette Spectroscopic Imaging (RSI) acquisition to other spectroscopic imaging experiments is outlined. Accounting for hardware constraints, trajectory parameters that provide for optimal sampling and minimal artifact production are found. Along with an analytical expression for the number of excitations to be used in an RSI experiment that is provided, the theoretical precompensation weights used for optimal image reconstruction are derived. RESULTS: The spectral response function for RSI is shown to be approximately the same as the point spread function of standard Fourier reconstructions. While the signal-to-noise ratio (SNR) for an RSI experiment is reduced by the inherent nonuniform sampling of these trajectories, their circular k-space support and speed of spatial encoding leads to greater SNR efficiency and improvements in the total data acquisition time relative to the gold standard CSI approach with square k-space support and to similar efficiency to spiral CSI acquisitions. Numerical simulations and in vivo experimental data are presented to demonstrate the properties of this data acquisition technique. CONCLUSION: This work demonstrates the use of Rosette trajectories and how to achieve improved efficiency for these trajectories in a two-dimensional spectroscopic imaging experiment.
Authors: Adam M Bush; Christopher M Sandino; Shreya Ramachandran; Frank Ong; Nicholas Dwork; Evan J Zucker; Ali B Syed; John M Pauly; Marcus T Alley; Shreyas S Vasanawala Journal: J Magn Reson Imaging Date: 2020-05-26 Impact factor: 4.813
Authors: Claudiu V Schirda; Tiejun Zhao; Victor E Yushmanov; Yoojin Lee; Gena R Ghearing; Frank S Lieberman; Ashok Panigrahy; Hoby P Hetherington; Jullie W Pan Journal: Magn Reson Med Date: 2017-09-14 Impact factor: 4.668
Authors: Claudiu V Schirda; Tiejun Zhao; Ovidiu C Andronesi; Yoojin Lee; Jullie W Pan; James M Mountz; Hoby P Hetherington; Fernando E Boada Journal: Magn Reson Med Date: 2015-08-26 Impact factor: 4.668