Urinary Metabolite Quantification Employing 2D NMR Spectroscopy

Gronwald, Wolfram; Klein, Matthias S.; Kaspar, Hannelore; Fagerer, Stephan R.; Nürnberger, N; Dettmer, Katja; Bertsch, Thomas; Oefner, Peter J.

doi:10.1021/ac801627c

Cited by 122 publications

(148 citation statements)

References 16 publications

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“…Using established protocols (Gronwald et al 2008), selected compounds from aqueous and lipophilic extracts were quantified using 2D and 1D spectra, respectively. In the lipophilic extracts, concentrations were calculated relative to the signal of the CHCl 3 fraction contained in CDCl 3 .…”

Section: Discussionmentioning

confidence: 99%

“…Glucose showed high values only in IC 2 and separated the steatosis group from the other two groups. Quantitative data for the metabolites identified, except for betaine that could not be measured above the lower limit of quantification (LLOQ) (Gronwald et al 2008), and the P-values for the ANOVA tests and all t-statistics are given in Table 2. For taurine significantly increased values were found in the steatosis group compared to both the control and the NASH group.…”

Section: Hydrophilic Liver Extractsmentioning

confidence: 99%

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Discrimination of steatosis and NASH in mice using nuclear magnetic resonance spectroscopy

Klein

Dorn²,

Saugspier³

et al. 2010

Metabolomics

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Nonalcoholic fatty liver disease (NAFLD) is a common cause of hepatic dysfunction. The disease spectrum ranges from hepatic steatosis to nonalcoholic steatohepatitis (NASH). The aim of this study was to identify metabolic differences in murine models of simple hepatic steatosis and NASH for the distinction of these NAFLD stages. For 12 weeks, male BALB/c mice were fed either a control or two different high-fat diets leading to hepatic steatosis and NASH, respectively. Metabolic differences were determined by independent component analysis (ICA) of nuclear magnetic resonance (NMR) spectra of lipophilic and hydrophilic liver extracts, and urine specimens. The results from ICA clearly discriminated the three investigated groups. Discriminatory biomarkers in the lipophilic liver extracts were free cholesterol, cholesterol ester and lipid methylene. Discrimination of the hydrophilic liver extracts was mainly mediated by betaine, glucose, and lactate, whereas in urine taurine, trimethylamine-N-oxide, and trimethylamine were the most discriminatory biomarkers. In conclusion, NMR metabolite fingerprinting of spot urine specimens may allow the noninvasive distinction of steatosis and NASH.

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Section: Discussionmentioning

confidence: 99%

Section: Hydrophilic Liver Extractsmentioning

confidence: 99%

Discrimination of steatosis and NASH in mice using nuclear magnetic resonance spectroscopy

Klein

Dorn²,

Saugspier³

et al. 2010

Metabolomics

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“…Heteronuclear ( 1 H→ 13 C) correlation spectroscopy can in principle offer a satisfactory dispersion. 5,6 So far, 13 C NMR is not routinely used in metabolomic studies, but hyperpolarization by dissolution dynamic nuclear polarization (D-DNP) combined with cross polarization (CP) could boost its popularity in this field.Hyperpolarization techniques are capable of generating spin polarization levels that are about 50 000 times above Boltzmann equilibrium at room temperature. 7-9 Once prepared and transferred to a solution-state NMR spectrometer, the resulting magnetization can be exploited within a limited time-span that depends on the longitudinal relaxation time T 1 of the hyperpolarized nuclei.…”

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confidence: 99%

Hyperpolarized NMR of plant and cancer cell extracts at natural abundance

Dumez

Milani

Vuichoud

et al. 2015

Analyst

103

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Natural abundance 13 C NMR spectra of biological extracts are recorded in a single scan provided that the samples are hyperpolarized by dissolution dynamic nuclear polarization combined with cross polarization. Heteronuclear 2D correlation spectra of hyperpolarized breast cancer cell extracts can also be obtained in a single scan. Hyperpolarized NMR of extracts opens many perspectives for metabolomics.Lying at the interface of chemistry and biology, metabolomics is one of the youngest sprouts of the sprawling tree of "omic" sciences. The last decade has witnessed a growing interest in mapping metabolic pathways, in identifying new biomarkers, and in modeling metabolic fluxes. 1,2 Nuclear Magnetic Resonance (NMR) spectroscopy is a major analytical technique in this field, offering unambiguous information about the identity of metabolites and their time-dependent concentrations in complex samples such as biofluids, extracts and tissues. However, proton NMR spectra have a limited range of chemical shifts and often suffer from overlapping signals. Carbon-13, which has a larger chemical shift dispersion, can benefit from sensitive detectors 3 or from isotopic enrichment, 4 albeit at the cost of an enhanced complexity of the spectra due to 13 C-13 C couplings. Heteronuclear ( 1 H→ 13 C) correlation spectroscopy can in principle offer a satisfactory dispersion. 5,6 So far, 13 C NMR is not routinely used in metabolomic studies, but hyperpolarization by dissolution dynamic nuclear polarization (D-DNP) combined with cross polarization (CP) could boost its popularity in this field.Hyperpolarization techniques are capable of generating spin polarization levels that are about 50 000 times above Boltzmann equilibrium at room temperature. 7-9 Once prepared and transferred to a solution-state NMR spectrometer, the resulting magnetization can be exploited within a limited time-span that depends on the longitudinal relaxation time T 1 of the hyperpolarized nuclei. Among various methods for hyperpolarization, dynamic nuclear polarization (DNP) is least affected by the chemical substrate and sample preparation. 10 For solution-state NMR, particularly promising results can be obtained by dissolution DNP, where the sample to be analyzed is mixed with free radicals in a glass-forming solution, frozen to liquid helium temperatures, and hyperpolarized by irradiating in the vicinity of the electron spin resonance (ESR) of the unpaired electrons of the radicals. 11 Spins of 13 C nuclei may be polarized either directly or via cross-polarization from protons to 13 C. 12 Rapid melting and shuttling of the sample from the polarizer to a routine NMR spectrometer enables conventional solution-state NMR spectroscopy with a sensitivity that can be boosted by a factor of about 50 000. Most applications of D-DNP have been restricted to the injection of pure hyperpolarized 13 C-labeled molecules such as pyruvate into living organisms. 13 D-DNP has hardly been applied to complex mixtures of metabolites, 14 but only to a few wellchosen small molecules...

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“…However, the direct quantitative properties observed in 1 H-NMR cannot be extrapolated to 2D-NMR and especially in 2D-COSY. Indeed, cross-peak intensities are influenced by other factors than concentration such as relaxation times, mixing times, evolution times, uneven magnetization transfers, coupling constants (J)… (10)(11)(12). Moreover, the influence of the biological matrix has to be taken into account and the presence of a huge amount of water requires the use of adapted pulse sequences including a pre-saturation step in order to drastically reduce the water signal which can greatly impact the quality of the spectra.…”

Section: Introductionmentioning

confidence: 99%

2D-Cosy NMR Spectroscopy as a Quantitative Tool in Biological Matrix: Application to Cyclodextrins

Dufour

Évrard

Tullio

2015

AAPS J

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Abstract. Classical analytical quantifications in biological matrices require time-consuming sample pretreatments and extractions. Nuclear magnetic resonance (NMR) analysis does not require heavy sample treatments or extractions which therefore increases its accuracy in quantification. In this study, even if quantitative (q)NMR could not be applied to 2D spectra, we demonstrated that cross-correlations and diagonal peak intensities have a linear relationship with the analyzed pharmaceutical compound concentration. This work presents the validation process of a 2D-correlation spectroscopy (COSY) NMR quantification of 2-hydroxypropyl-β-cyclodextrin in plasma. Specificity, linearity, precision (repeatability and intermediate precision), trueness, limits of quantification (LOQs), and accuracy were used as validation criteria. 2D-NMR could therefore be used as a valuable and accurate analytical technique for the quantification of pharmaceutical compounds, including hardly detectable compounds such as cyclodextrins or poloxamers, in complex biological matrices based on a calibration curve approach.

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Urinary Metabolite Quantification Employing 2D NMR Spectroscopy

Cited by 122 publications

References 16 publications

Discrimination of steatosis and NASH in mice using nuclear magnetic resonance spectroscopy

Discrimination of steatosis and NASH in mice using nuclear magnetic resonance spectroscopy

Hyperpolarized NMR of plant and cancer cell extracts at natural abundance

2D-Cosy NMR Spectroscopy as a Quantitative Tool in Biological Matrix: Application to Cyclodextrins

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