Direct in vivo measurement of glycine and the neurochemical profile in the rat medulla oblongata

The medulla oblongata (MO) contains a high density of glycinergic synapses and a particularly high concentration of glycine The aims of this study were to measure directly in vivo the neurochemical profile, including glycine, in MO using a spin-echo-based H-1 MRS sequence at TE = 2 8 ms and to compare it with three other brain regions (cortex, striatum and hippocampus) in the rat Glycine was quantified in MO at TE = 2 8 ms with a Cramer-Rao lower bound (CRIB) of approximately 5% As a result of the relatively low level of glycine in the other three regions, the measurement of glycine was performed at TE = 20 ms, which provides a favorable J-modulation of overlapping myo-inositol resonance The other 14 metabolites composing the neurochemical profile were quantified in vivo in MO with CRLBs below 25% Absolute concentrations of metabolites in MO, such as glutamate, glutamine, gamma-aminobutyrate, taurine and glycine, were in the range of previous in vitro quantifications in tissue extracts Compared with the other regions, MO had a three-fold higher glycine concentration, and was characterised by reduced (p < 0 001) concentrations of glutamate (-50 +/- 4%), glutamine (-54 +/- 3%) and taurine (-78 +/- 3%) This study suggests that the functional specialisation of distinct brain regions is reflected in the neurochemical profile Copyright (C) 2010 John Wiley & Sons, Ltd

Development and implementation of ¹H magnetic resonance techniques for an improved in vivo assessment of models of cerebral metabolic disorders

Mélanie Craveiro

Nuclear magnetic resonance (NMR) is a physical phenomenon that is widely used in the biomedical field due to its non-invasive and non-destructive properties, which make it an optimal tool for the in vivo investigation of living organs such as the brain. This thesis focused on the development of 1H magnetic resonance (MR) techniques at ultra-high magnetic field strength to improve the measurement and quantification of the 1H MR signal in the rodent brain, and to accurately assess the alterations of the metabolite and water concentrations in several cerebral metabolic disorders. In rodents, 1H MR spectroscopy (MRS) allows the assessment of the concentration of up to 20 metabolites that take part in many cerebral metabolic processes such as neurotransmission, cell energy metabolism, cell growth and osmosis. 1H MRS thus provides a unique tool to non-invasively investigate the cerebral metabolism in healthy and pathological conditions in vivo. However, it is essential for reliable quantification that systematic errors and overlap of the measured metabolite signals are minimized. To that aim, the impact of a potential additional short T2 relaxation time component, which might affect the glutamine quantification at long echo times, was assessed in this thesis. The J-difference editing technique MEGA-SPECIAL was optimized to obtain the unequivocal detection of the glutamine signal at moderate echo time. As a control, the glutamine concentration obtained with this method was then compared to short echo time 1H MR spectroscopy measurements. Since the two measurements of the glutamine concentration at short and moderate echo time did not result in significant differences, this study concluded that there is a low probability of an effect of a short T2 relaxation time component on the glutamine concentration measurement. Since a reliable quantification of 1H spectra partly relies on the accurate assessment of the overlapping macromolecule contribution to the metabolites, an optimized method for the post-processing of the measured macromolecule signal was developed to ensure an accurate assessment of its contribution. This method was applied to investigate potential regional differences in the mouse brain macromolecule signals that may affect metabolite quantification when not taken into account, as well as for the assessment of macromolecule alterations in a human-glioma mouse model. No regional macro- molecule variation was found to significantly affect the metabolite quantification in the healthy mouse brain, which supports the common use of a general macromolecule spec- trum for healthy rodent brain 1H spectra quantification. However, several alterations of the macromolecule spectrum, some of which were reported for the first time, were observed in glioma tissues, and their accurate assessment was shown to be necessary for reliable metabolite quantification. Localized 1H MR spectroscopy techniques that are designed to acquire the1H MR signal from a 3D volume can also be combined with MR imaging (MRI) to acquire information on the spatial distribution of the individual metabolites, which is often of interest when heterogeneous tissues are investigated (such as in pathological conditions). This MR spectroscopic imaging (MRSI) technique is however limited in its conventional implementation by the long measurement time that is necessary to acquire the spatial information. A fast MRSI technique, spectroscopic RARE (spRARE), was therefore implemented at high magnetic field strength in this thesis in order to benefit from the advantage of high magnetic fields in addition to the rapid spatial encoding scheme offered by spRARE. Several optimizations of the metabolite signal detection were implemented in spRARE, before the efficiency of the technique was validated at 9.4 T through a comparison of the acquired in vitro metabolite signals with numerical simulations using the density matrix formalism. The in vivo quantification of the water content is also of interest as it offers perspec- tives for investigating cerebral disease progression that is associated with brain water content alterations. In addition, when the water signal is used as an internal reference for metabolite concentration quantification in MRS, such knowledge can also contribute to a more reliable quantification. A method that is based on the multi-spin-echo MRI technique was therefore developed for the absolute quantification of the water content in the rodent brain, with the aim of assessing alterations of its content in pathological conditions. It was then applied on a bile-duct-ligation rat model of chronic hepatic encephalopathy (HE) to assess the brain water content changes associated with the disease as well as its metabolic alterations. The absence of significant brain water content changes detected in the investigated HE rat model, which was supported by post-mortem brain water content measurements using gravimetry and the dry/wet weight-ratio technique, potentially opens the way for investigating cerebral metabolic processes in chronic HE in absence of edema formation. Localized 1H MRS and conventional MRSI were also applied for the investigation of rodent models of brain disorders in order to assess the metabolic profile associated with those disorders. These studies for the first time allowed the assessment of GABA as a potential early Parkinson’s disease marker, while they also provided new insights into the role of the PPAR-β brain receptor in the early neuroprotective effects following ischemia.

EPFL2013

Improved ¹H-[¹³C] and ¹H NMR methods for in vivo measurement of cerebral metabolism

Lijing Xin

Nuclear magnetic resonance (NMR) spectroscopy can be applied in vivo to measure static or dynamic biochemical information, e.g., concentrations of metabolites and metabolic fluxes, using various nuclei such as 1H, 13C, 31P and 15N. The work of this thesis involves both 1H and 13C nuclei and focuses on improving 1H NMR detection methods for measuring metabolites in vivo in rat brain. 13C NMR spectroscopy can be used to monitor the flow of 13C label from a 13C enriched substrate, such as glucose or acetate, into different NMR detectable metabolites, e.g., glutamate (Glu) and glutamine (Gln), for the quantitative study of cerebral metabolism in vivo. 1H-observed 13C-edited (1H-[13C]) NMR spectroscopy is an alternative to direct 13C NMR detection of 13C labeled metabolites, allowing a higher spatial and temporal resolution, albeit at a lower spectral resolution. In this context, a hybrid full signal intensity 1H-[13C] NMR sequence, combining a 13C editing block based on an inversion B1 insensitive spectral editing pulse (BISEP) with a spin-echo based localization (SPECIAL), was developed and implemented at ultra-high magnetic field (14.1 T) to benefit from increased sensitivity and spectral resolution at high B0. As a result, high quality 1H-[13C] NMR spectra were obtained, leading to an improved quantification of 13C labeled metabolites, which allowed the measurement of time courses of Glu C4, Gln C4, as well as, for the first time, of Glu C3 and of Gln C3, with high temporal resolution from a small acquisition volume. Although at high magnetic field spectral resolution and sensitivity are improved, spectral overlap is still present, e.g., the N-acetylaspartate (NAA) C6 is easily obscured by the intensive labeling of Glu C3 and Gln C3 (Glx C3), due to their complex coupling patterns. To improve the detection of unresolved 13C labeled metabolites, we developed an alternative 1H-[13C] NMR editing sequence termed RACED-STEAM (selective Resonances suppression by Adiabatic Carbon Editing and Decoupling single-voxel STimulated Echo Acquisition Mode), which can selectively suppress 1H resonances bound to a specific 13C to uncover resonances that are difficult to resolve in the 1H-[13C] NMR spectrum. Results showed the efficient suppression of Glx C3 and Glu C4, allowing the detection of NAA C6 and Gln C4 at 9.4 T. The application of this method to measure the time course of NAA C6 demonstrated that NAA C6 turnover can be measured at very low levels of isotopic enrichment in a small volume, within a time frame of a few hours. The proposed scheme could also be extended to lower magnetic fields provided that the 13C chemical shifts remain sufficiently resolved. Similarly, due to limited spectral resolution and sensitivity, editing techniques for the in vivo detection of metabolites using 1H NMR spectroscopy are still in development. Many in vivo 1H NMR editing sequences are usually performed at moderate to long echo times (TE). Furthermore, several 1H NMR spectroscopy studies are performed at long TE to avoid the confounding effect of macromolecular signals on metabolite quantification. In such cases, proton T2 relaxation times of metabolites have to be taken into account for proper quantification of metabolite concentrations. While T2 relaxation times of singlets have been characterized in several studies, due to the relative experimental simplicity, similar information is lacking from coupled spin resonances of cerebral metabolites. In this thesis, spectral simulations based on the density matrix formalism were initially performed to predict the response of spin systems to the pulse sequence used. T2 relaxation times of coupled spin resonances and singlet resonances of cerebral metabolites were then measured in rat brain in vivo at 9.4 T. Data analysis was performed using LCModel combined with simulated TE-specific spectra. The aforementioned spectral simulations were further used to optimize pulse sequence parameters for the detection of metabolites, such as glycine, whose resonance signal is overlapped with the more intense myo-inositol resonances. A favorable short TE (i.e., 20 ms) was sufficient to reduce the signal intensity of myo-inositol, allowing the detection of glycine in vivo in rat brain at 9.4 T. This work suggests that at high magnetic fields, glycine can be measured at a relatively short TE without additional editing efforts. Moreover, glycine is present at a particularly high concentration in the medulla oblongata (MO). Therefore, we further measured regional distribution of glycine in the hippocampus, cortex, striatum and MO of the rat brain, as well as the highly specific neurochemical profile of the MO. In conclusion, dedicated approaches for 1H NMR detection developed and validated in this thesis lead to improved dynamic measurement of 13C labeling time courses such as the time courses of 13C labeling of Glu C3 and Gln C3, as well as the spectral resolved NAA C6, the direct in vivo detection of glycine in rat brain at 9.4 T and the measurement of T2 relaxation times of numerous J-coupled metabolites for the first time.

EPFL2009

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

Cristina Ramona Cudalbu, Rolf Gruetter, Lijing Xin

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, gamma-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 H-1 NMR spectroscopy. This implies that the quantification of the neurochemical profile in rodent brain can be achieved with improved accuracy and precision. (C) 2008 Elsevier Inc. All rights reserved.