Measuring gluconeogenesis using a low dose of 2H2O: advantage of isotope fractionation during gas chromatography.

The contribution of gluconeogenesis to glucose production can be measured by enriching body water with (2)H(2)O to approximately 0.5% (2)H and determining the ratio of (2)H that is bound to carbon-5 vs. carbon-2 of blood glucose. This labeling ratio can be measured using gas chromatography-mass spectrometry after the corresponding glucose carbons are converted to formaldehyde and then to hexamethylenetetramine (HMT). We present a technique for integrating ion chromatograms that allows one to use only 0.05% (2)H in body water (i.e., 10 times less than the current dose). This technique takes advantage of the difference in gas chromatographic retention times of naturally labeled HMT and [(2)H]HMT. We discuss the advantage(s) of using a low dose of (2)H(2)O to quantify the contribution of gluconeogenesis.

Gas chromatography-mass spectrometry assay of the (18)o enrichment of water as trimethyl phosphate.

We have developed an assay for determining the 18O enrichment of water in biological fluids. Urine, plasma, or whole blood is reacted with phosphorous pentachloride to yield phosphoric acid. Derivatization of phosphoric acid with diazomethane generates trimethyl phosphate. The enrichment of trimethyl phosphate is nearly four times that of water and is assayed using gas chromatography-mass spectrometry (electron impact ionization). Yang et al. (1998, Anal. Biochem. 258, 315-321) assayed the 2H enrichment of body water after exchange with acetone, by gas chromatography-mass spectrometry. The combination of our 18O method and the 2H method of Yang et al. allows one to measure energy expenditure via "doubly labeled" water (2H(2)O + H(2)18O), using small samples of body fluids. These techniques were used to measure energy expenditure in mice, in which the 18O enrichment of body water can be monitored down to 0.025%.