Proton-decoupled 13C NMR spectra of the human head were obtained during hyperglycemic glucose clamping using intravenous infusions of [1-13C]glucose in normal volunteers. In addition to 13C signals of mobile lipids, a variety of new metabolite resonances could be resolved for the first time in the human brain. At an enrichment level of 20% [1-13C]glucose, the signals of alpha- and beta-glucose at 92.7 and 96.6 ppm, respectively, could be detected in the human brain after only an infusion period of 15 min. The spatial localization of the different regions of interest was confirmed by 13C NMR spectroscopic imaging with a time resolution of 9 min. Increasing the enrichment level to 99% [1-13C]glucose not only improved the time resolution but allowed the detection of metabolic breakdown products of [1-13C]glucose. The time course of 13C label incorporation into the C2, C3, and C4 resonances of glutamate/glutamine and into lactate could be recorded in the human brain. These results suggest the possibility of obtaining time-resolved, spatially selective, and chemically specific information on the human body.
The metabolic effects of recombinant human insulin-like growth factor-I (IGF-I) were assessed in five groups of normal male overnight-fasted volunteers receiving infusions of either 0, 5, 7.5, 15, or 30 micrograms/kg.h IGF-I during 8 h, resulting in total plasma IGF-I concentrations 127 +/- 7, 247 +/- 30, 389 +/- 39, 573 +/- 62, 620 +/- 105 ng/ml, respectively. Glucose consumption (euglycemic glucose clamp) increased dose dependently during IGF-I infusion (P < 0.001) up to 6.7 +/- 1.3 mg/kg. min in the 30 micrograms/kg.h group. Plasma triglyceride concentrations decreased with increasing doses of IGF-I (P < 0.03); the fall was 43% in the 30 micrograms/kg.h group. Plasma free fatty acid concentrations decreased during 7.5, 15, and 30 micrograms/kg.h IGF-I by 23%, 34%, and 48%, respectively. IGF-I lowered plasma beta-hydroxybutyrate concentrations in a dose-dependent manner (P < 0.025). Plasma concentrations of leucine and alpha-ketoisocaproate decreased dose dependently (P < 0.001 and P < 0.015). Whole body leucine flux (1-13C-leucine infusion technique) decreased with increasing doses of IGF-I by 41% during 30 micrograms/kg.h, indicating decreased whole body protein breakdown. Leucine oxidation into 13CO2 decreased with increasing doses of IGF-I (P < 0.045) by 57% in the 30 micrograms/kg.h group, suggesting inhibition of irreversible loss of leucine. Plasma C-peptide and insulin concentrations decreased dose dependently (P < 0.005 and P < 0.02), indicating diminished insulin secretion. Thus, acute elevation of plasma IGF-I concentrations in man results in metabolic effects which are qualitatively similar to those described previously of insulin.
The formation of glycogen in the liver of normal volunteers was followed noninvasively with 13C magnetic resonance spectroscopy (MRS) under two different conditions: a) intravenous infusion of [1-13C]glucose under hyperglycemic and hyperinsulinemic clamp conditions, and b) oral intake of glucose in the form of a bolus. For the intravenous infusion, [1-13C]glucose with an enrichment level of 99% was employed. The C1 signals of alpha- and beta-glucose could be detected in the human liver already after an infusion period of 8 min. However, an increase in the glycogen signal was observed only after a prolonged infusion of about 60 min. Changes in the glycogen signal correlated well with the time course of insulin and glucagon during the measurement. Experiments showed also that liver glycogen formation in man can be followed noninvasively by 13C-MRS using nonlabeled glucose or [1-13C]glucose with a low level of enrichment (6.6%). The use of nonlabeled glucose may therefore simplify the quantitation of net liver glycogen synthesis since it can be based directly on changes in the natural abundance 13C MRS glycogen signal, avoiding label dilution through the various metabolic pathways of glucose. The glucose uptake, estimated from the increase in the glycogen signal, was consistent with findings from more complex and invasive studies of glucose uptake in the liver. The average liver glycogen concentration in 12 h overnight fasted volunteers (n = 18) without any special dietary preparation was assessed to be 229 +/- 34 mM (minimum = 160 mM; maximum = 274 mM).
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