Proton T1 and T2 relaxation times of human brain metabolites at 3 Tesla

Mlynárik, Vladı́mir; Gruber, Stephan; Moser, Ewald

doi:10.1002/nbm.713

Cited by 280 publications

(314 citation statements)

References 21 publications

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“…The benefits are especially expected to be important for metabolites having low concentration or overlapping spectral lines and for compounds giving complex J-coupled spectral patterns. Recent studies, however, have indicated that these advantages may be partially offset by a decrease of T 2 and T Ã 2 with increasing static magnetic field [2,3], with some predicting [4] a moderate increase of the signalto-noise ratio (SNR) and a nearly linear increase in the spectral linewidth (expressed in Hz) when increasing B 0 above 9.4 T.…”

Section: Introductionmentioning

confidence: 99%

1H NMR spectroscopy of rat brain in vivo at 14.1Tesla: Improvements in quantification of the neurochemical profile

Mlynarik

Cudalbu

Xin

et al. 2008

Journal of Magnetic Resonance

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141

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Keywords:Proton single voxel spectroscopy Ultra high magnetic field of 14.1 T Rat brain LCModel Quantification accuracy a b s t r a c t Ultra-short echo-time proton single voxel spectra of rat brain were obtained on a 14.1 T 26 cm horizontal bore system. At this field, the fitted linewidth in the brain tissue of adult rats was about 11 Hz. New, separated resonances ascribed to phosphocholine, glycerophosphocholine and N-acetylaspartate were detected for the first time in vivo in the spectral range of 4.2-4.4 ppm. Moreover, improved separation of the resonances of lactate, alanine, c-aminobutyrate, glutamate and glutathione was observed. Metabolite concentrations were estimated by fitting in vivo spectra to a linear combination of simulated spectra of individual metabolites and a measured spectrum of macromolecules (LCModel). The calculated concentrations of metabolites were generally in excellent agreement with those obtained at 9.4 T. These initial results further indicated that increasing magnetic field strength to 14.1 T enhanced spectral resolution in 1 H NMR spectroscopy. This implies that the quantification of the neurochemical profile in rodent brain can be achieved with improved accuracy and precision.

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Section: Introductionmentioning

confidence: 99%

1H NMR spectroscopy of rat brain in vivo at 14.1Tesla: Improvements in quantification of the neurochemical profile

Mlynarik

Cudalbu

Xin

et al. 2008

Journal of Magnetic Resonance

Self Cite

103

141

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“…Determining their relaxation constants from experimental data collected with spin-echo sequences is common in diffusion tensor imaging (DTI) and spectroscopy (DTS) [1][2][3], measurements of fractional anisotropy (FA) [4], transverse relaxation rates (R 2 ) [5][6][7], etc. An exponentially decaying signal can be described by two parameters: its amplitude ρ and decay rate λ, (1) where t is the user-controlled encoding parameter (diffusion weighting or echo time).…”

Section: Introductionmentioning

confidence: 99%

The optimal MR acquisition strategy for exponential decay constants estimation

Fleysher

Gonen

2008

Magnetic Resonance Imaging

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Estimating the relaxation constant of an exponentially decaying signal from experimental MR data is fundamental in diffusion tensor imaging, fractional anisotropy mapping, measurements of transverse relaxation rates and contrast agent uptake. The precision of such measurements depends on the choice of acquisition parameters made at the design stage of the experiments. In this report, χ 2 fitting of multi-point data is used to demonstrate that the most efficient acquisition strategy is a two-point scheme. We also conjecture that the smallest cofficient of variation of the decay constant achievable in any N-point experiment is 3.6 times larger than that in the image intensity obtained by averaging N acquisitions with minimal exponential weighting.

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“…While the T 1 relaxation time of water protons is significantly longer at 3 T as compared to 1.5 T, metabolite T 1 measurements can be either longer [34] or almost unchanged [35,36]. The discrepancies can be explained by the large interindividual variability at 1.5 T and the possible differences in scanner performance, sequence design and strategies for acquiring and evaluating spectra.…”

Section: Spectral Resolution and Metabolite Quantificationmentioning

confidence: 99%