Optimization of fast spiral chemical shift imaging using least squares reconstruction: Application for hyperpolarized 13C metabolic imaging

A least‐squares–based optimization and reconstruction algorithm has been developed for rapid metabolic imaging in the context of hyperpolarized 13C. The algorithm uses a priori knowledge of resonance frequencies, J‐coupling constants, and T2* values to enable acquisition of high‐quality metabolic images with imaging times of approximately 100 ms for an 8‐cm field of view (FOV) and 0.5 cm isotropic resolution. A root‐mean‐square error (rMSE) analysis is introduced to optimize metabolic image quality by appropriate choice of pulse sequence parameters, echo times, and signal model. By performing the reconstruction in k‐space, the algorithm also allows the inclusion of the effect of chemical shift evolution during the readout period. Single‐interleaf multiecho spiral chemical shift imaging (spCSI) is analyzed in detail as an illustrative example for the use of the new reconstruction and optimization algorithm. Simulation of the in vivo spectrum following the bolus injection of hyperpolarized 13C1 pyruvate shows that single‐interleaf spiral spectroscopic imaging can achieve image quality in 100 ms, comparable to the performance of a 13‐s phase‐encoded chemical shift imaging (FIDCSI) experiment. Single‐interleaf spCSI was also tested at a 3‐T MR scanner using a phantom containing approximately 0.5‐M solutions of alanine, lactate, and a pyruvate‐pyruvate hydrate C1‐C2 ester at thermal equilibrium polarization, all enriched to 99% 13C in the C1 carbonyl positions. Upon reconstruction using the k‐space–based least‐squares technique, metabolite ratios obtained using the spCSI method were comparable to those obtained using a reference FIDCSI acquisition. Magn Reson Med 58:245–252, 2007. © 2007 Wiley‐Liss, Inc.

[1]  A Macovski,et al.  Inhomogeneity correction for in vivo spectroscopy by high‐resolution water referencing , 1992, Magnetic resonance in medicine.

[2]  F. Jolesz,et al.  Gradient-Echo Imaging Considerations for Hyperpolarized 129Xe MR , 1996, Journal of magnetic resonance. Series B.

[3]  John M Pauly,et al.  Echo time optimization for linear combination myelin imaging , 2005, Magnetic resonance in medicine.

[4]  Hisamoto Moriguchi,et al.  Dixon techniques in spiral trajectories with off‐resonance correction: A new approach for fat signal suppression without spatial‐spectral RF pulses , 2003, Magnetic resonance in medicine.

[5]  R. London 13C labeling in studies of metabolic regulation , 1988 .

[6]  Jan Henrik Ardenkjaer-Larsen,et al.  Metabolic imaging by hyperpolarized 13C magnetic resonance imaging for in vivo tumor diagnosis. , 2006, Cancer research.

[7]  G. Gold,et al.  Iterative decomposition of water and fat with echo asymmetry and least‐squares estimation (IDEAL): Application with fast spin‐echo imaging , 2005, Magnetic resonance in medicine.

[8]  K. Scheffler,et al.  Fast chemical shift mapping with multiecho balanced SSFP , 2006, Magnetic Resonance Materials in Physics, Biology and Medicine.

[9]  J. Ardenkjær-Larsen,et al.  Increase in signal-to-noise ratio of > 10,000 times in liquid-state NMR , 2003, Proceedings of the National Academy of Sciences of the United States of America.

[10]  D G Nishimura,et al.  MR imaging of articular cartilage using driven equilibrium , 1999, Magnetic resonance in medicine.

[11]  L Zhao,et al.  Gradientecho imaging considerations for hyperpolarized ^ Xe MR , 1996 .

[12]  W. T. Dixon Simple proton spectroscopic imaging. , 1984, Radiology.

[13]  J A Romijn,et al.  Lactate-pyruvate interconversion in blood: implications for in vivo tracer studies. , 1994, The American journal of physiology.

[14]  W Dreher,et al.  A fast variant of (1)H spectroscopic U-FLARE imaging using adjusted chemical shift phase encoding. , 2000, Journal of magnetic resonance.

[15]  G. Glover Multipoint dixon technique for water and fat proton and susceptibility imaging , 1991, Journal of magnetic resonance imaging : JMRI.

[16]  Douglas C. Noll,et al.  Deblurring for non‐2D fourier transform magnetic resonance imaging , 1992, Magnetic resonance in medicine.

[17]  Norbert J Pelc,et al.  Field map estimation with a region growing scheme for iterative 3‐point water‐fat decomposition , 2005, Magnetic resonance in medicine.

[18]  Dirk Mayer,et al.  Fast metabolic imaging of systems with sparse spectra: Application for hyperpolarized 13C imaging , 2006, Magnetic resonance in medicine.

[19]  J Stefan Petersson,et al.  Metabolic imaging and other applications of hyperpolarized 13C1. , 2006, Academic radiology.

[20]  A. Macovski,et al.  Volumetric spectroscopic imaging with spiral‐based k‐space trajectories , 1998, Magnetic resonance in medicine.

[21]  D. Nishimura,et al.  Reduced aliasing artifacts using variable‐density k‐space sampling trajectories , 2000, Magnetic resonance in medicine.

[22]  M. Thaning,et al.  Real-time metabolic imaging. , 2006, Proceedings of the National Academy of Sciences of the United States of America.

[23]  G H Glover,et al.  Three‐point dixon technique for true water/fat decomposition with B0 inhomogeneity correction , 1991, Magnetic resonance in medicine.

[24]  Jan H. Ardenkjær-Larsen,et al.  Molecular imaging with endogenous substances , 2003, Proceedings of the National Academy of Sciences of the United States of America.

[25]  Peter Magnusson,et al.  13C imaging—a new diagnostic platform , 2005, European Radiology.

[26]  Norbert J Pelc,et al.  Cramér–Rao bounds for three‐point decomposition of water and fat , 2005, Magnetic resonance in medicine.

[27]  Michael Markl,et al.  Multicoil Dixon chemical species separation with an iterative least‐squares estimation method , 2004, Magnetic resonance in medicine.