Effects of glucocorticoids on hepatic sensitivity to insulin and glucagon in man.

in Clinical Nutrition (2000), 19(1), 29-34

AIMS: This study was undertaken to determine the effects of a short-term dexamethasone treatment on hepatic sensitivities to insulin and glucagon. METHODS: Eleven healthy subjects were studied during one ... [more ▼]

AIMS: This study was undertaken to determine the effects of a short-term dexamethasone treatment on hepatic sensitivities to insulin and glucagon. METHODS: Eleven healthy subjects were studied during one or several of four protocols. In all protocols, somatostatin was infused continuously to inhibit pancreatic hormone secretion. In protocol 1, basal insulin was infused over 300 min while glucagon was infused at a rate of 0.5 mg/kg(-1)/min(-1)during 180 min, then at a rate of 1.5 ng/kg(-1)/min(-1)during 150 min. In protocol 2, the same experiment was performed after a 2 day treatment with 8 mg/day dexamethasone. In protocol 3, the two-step glucagon infusion was performed during insulin infusion at a rate aimed to reproduce the hyperinsulinemia observed during protocol 2. In protocol 4, continuous basal insulin and low glucagon (0.5 mg/kg(-1)/min(-1)) were infused over 330 min. RESULTS: In protocol 1, plasma glucose rose transiently by 2.0 +/- 0.3 mmol/l when the glucagon rate was increased and glucose production increased by 1.4 +/- 0.5 micromol/kg(-1)/min(-1). In protocol 2, the insulin infusion rate (1.85 +/- 0.36 nmol/kg(-1)/min(-1)) required to maintain glycemia was 3.3-fold higher than during protocol 1. Glucagon-induced stimulation of glycemia (by 1.47 +/- 0.5 mmol/l) and endogenous glucose production (by 0.8 +/- 0.3 micromol/kg(-1)/min(-1)) were blunted, but not abolished. In protocol 3, endogenous glucose production was suppressed by 75% by hyperinsulinemia and was not stimulated when the glucagon infusion rate was increased. In protocol 4, endogenous glucose production did not change significantly with time. CONCLUSION: These results indicate that high dose glucocorticoids induce a marked hepatic insulin resistance. Stimulation of glucose production by hyperglucagonemia was maintained in spite of hyperinsulinemia which can be attributed to either hepatic insulin resistance and/or increased hepatic glucagon sensitivity. [less ▲]

Non oxidative fructose disposal is not inhibited by lipids in humans.

in Diabètes & Métabolism (1999), 25(3), 233-40

Elevated free fatty acid concentrations are known to decrease insulin-mediated glucose uptake, glucose oxidation and glycogen synthesis. In order to determine whether free fatty acids inhibit glycogen ... [more ▼]

Elevated free fatty acid concentrations are known to decrease insulin-mediated glucose uptake, glucose oxidation and glycogen synthesis. In order to determine whether free fatty acids inhibit glycogen synthesis at the level of liver cells, the effects of an infusion of lipids on carbohydrate metabolism were investigated in healthy subjects during a two-step (16.7 and 33.4 mumol/(kg.min) 13C-fructose infusion. Fructose infusion dose-dependently stimulated fructose (measured from 13CO2 production) and net carbohydrate oxidation (measured with indirect calorimetry). It also stimulated systemic 13C glucose appearance, indicating a dose-dependent stimulation of gluconeogenesis. Net glucose output (measured with 6,6 2H glucose) was however not altered. Lipid infusion significantly reduced fructose oxidation (measured from 13CO2 production) at both rates of fructose infusion, but did not alter plasma fructose or lactate concentrations, nor plasma 13C glucose appearance or net glucose production. Non oxidative fructose disposal was increased by 31% (p < 0.05) at the lowest, and by 18% (p < 0.01) at the highest infusion rate. Since nonoxidative fructose disposal corresponds mainly to liver glycogen deposition, these results suggest that lipid infusion increased hepatic glycogen synthesis, and hence that hepatic glycogen synthase is not inhibited by fatty acids. [less ▲]

Effects of Ingested Fructose and Infused Glucagon on Endogenous Glucose Production in Obese Niddm Patients, Obese Non-Diabetic Subjects, and Healthy Subjects

in Diabetologia (1996), 39(5), 580-6

Increased endogenous glucose production (EGP) and gluconeogenesis contribute to the pathogenesis of hyperglycaemia in non-insulin-dependent diabetes mellitus (NIDDM). In healthy subjects, however, EGP ... [more ▼]

Increased endogenous glucose production (EGP) and gluconeogenesis contribute to the pathogenesis of hyperglycaemia in non-insulin-dependent diabetes mellitus (NIDDM). In healthy subjects, however, EGP remains constant during administration of gluconeogenic precursors. This study was performed in order to determine whether administration of fructose increases EGP in obese NIDDM patients and obese non-diabetic subjects. Eight young healthy lean subjects, eight middle-aged obese NIDDM patients and seven middle-aged obese non-diabetic subjects were studied during hourly ingestion of 13C fructose (0.3 g.kg fat free mass-1.h-1) for 3 h. Fructose failed to increase EGP (measured with 6,6 2H glucose) in NIDDM (17.7 +/- 1.9 mumol.kg fat free mass-1.min-1 basal vs 15.9 +/- 0.9 after fructose), in obese non-diabetic subjects (12.1 +/- 0.5 basal vs 13.1 +/- 0.5 after fructose) and in lean healthy subjects (13.3 +/- 0.5 basal vs 13.8 +/- 0.6 after fructose) although 13C glucose synthesis contributed 73.2% of EGP in lean subjects, 62.6% in obese non-diabetic subjects, and 52.8% in obese NIDDM patients. Since glucagon may play an important role in the development of hyperglycaemia in NIDDM, healthy subjects were also studied during 13C fructose ingestion + hyperglucagonaemia (232 +/- 9 ng/l) and during hyperglucagonaemia alone. EGP increased by 19.8% with ingestion of fructose + glucagon (p < 0.05) but remained unchanged during administration of fructose or glucagon alone. The plasma 13C glucose enrichment was identical after fructose ingestion both with and without glucagon, indicating that the contribution of fructose gluconeogenesis to the glucose 6-phosphate pool was identical in these two conditions. We concluded that during fructose administration: 1) gluconeogenesis is increased, but EGP remains constant in NIDDM, obese non-diabetic, and lean individuals; 2) in lean individuals, both an increased glucagonaemia and an enhanced supply of gluconeogenic precursors are required to increase EGP; this increase in EGP occurs without changes in the relative proportion of glucose 6-phosphate production from fructose and from other sources (i.e. glycogenolysis + gluconeogenesis from non-fructose precursors). [less ▲]

Effects of ingested fructose and infused glucagon on endogenous glucose production in obese NIDDM patients, obese non-diabetic subjects, and healthy subjects.

in Diabetologia (1996), 39(5), 580-6

Increased endogenous glucose production (EGP) and gluconeogenesis contribute to the pathogenesis of hyperglycaemia in non-insulin-dependent diabetes mellitus (NIDDM). In healthy subjects, however, EGP ... [more ▼]

Increased endogenous glucose production (EGP) and gluconeogenesis contribute to the pathogenesis of hyperglycaemia in non-insulin-dependent diabetes mellitus (NIDDM). In healthy subjects, however, EGP remains constant during administration of gluconeogenic precursors. This study was performed in order to determine whether administration of fructose increases EGP in obese NIDDM patients and obese non-diabetic subjects. Eight young healthy lean subjects, eight middle-aged obese NIDDM patients and seven middle-aged obese non-diabetic subjects were studied during hourly ingestion of 13C fructose (0.3 g.kg fat free mass-1.h-1) for 3 h. Fructose failed to increase EGP (measured with 6,6 2H glucose) in NIDDM (17.7 +/- 1.9 mumol.kg fat free mass-1.min-1 basal vs 15.9 +/- 0.9 after fructose), in obese non-diabetic subjects (12.1 +/- 0.5 basal vs 13.1 +/- 0.5 after fructose) and in lean healthy subjects (13.3 +/- 0.5 basal vs 13.8 +/- 0.6 after fructose) although 13C glucose synthesis contributed 73.2% of EGP in lean subjects, 62.6% in obese non-diabetic subjects, and 52.8% in obese NIDDM patients. Since glucagon may play an important role in the development of hyperglycaemia in NIDDM, healthy subjects were also studied during 13C fructose ingestion + hyperglucagonaemia (232 +/- 9 ng/l) and during hyperglucagonaemia alone. EGP increased by 19.8% with ingestion of fructose + glucagon (p < 0.05) but remained unchanged during administration of fructose or glucagon alone. The plasma 13C glucose enrichment was identical after fructose ingestion both with and without glucagon, indicating that the contribution of fructose gluconeogenesis to the glucose 6-phosphate pool was identical in these two conditions. We concluded that during fructose administration: 1) gluconeogenesis is increased, but EGP remains constant in NIDDM, obese non-diabetic, and lean individuals; 2) in lean individuals, both an increased glucagonaemia and an enhanced supply of gluconeogenic precursors are required to increase EGP; this increase in EGP occurs without changes in the relative proportion of glucose 6-phosphate production from fructose and from other sources (i.e. glycogenolysis + gluconeogenesis from non-fructose precursors). [less ▲]

Assessment of glucose metabolism in humans with the simultaneous use of indirect calorimetry and tracer techniques.

in Clinical Physiology (1995), 15(1), 1-12

Concomitant measurements of sytemic glucose delivery and carbohydrate oxidation are frequently performed in human investigations. Systemic glucose delivery (SGD) is usually determined using dilution of ... [more ▼]

Concomitant measurements of sytemic glucose delivery and carbohydrate oxidation are frequently performed in human investigations. Systemic glucose delivery (SGD) is usually determined using dilution of infused glucose tracers; net carbohydrate oxidation rate (net CHOOX) can be calculated from respiratory gas exchanges and urinary nitrogen excretion (indirect calorimetry); alternatively, glucose oxidation can be measured from labelled CO2 production during infusion of carbon-labelled glucose tracers. In this paper, the theory underlying the use of each of these techniques is briefly reviewed and qualitative differences are outlined. SGD represents the sum of hepatic glucogenolysis, gluconeogenesis from amino acids or glycerol, and, according to the glucose tracer used, glucose cycles (glucose-phosphate cycle, fructose-phosphate cycle, Cori and glucose-alanine cycles); systemic delivery of exogenous glucose after oral or i.v. glucose administration is also measured. Net CHOOX represents oxidation of glucose arising from hepatic or muscle glycogen or from exogenous glucose; it does not take into account oxidation of glucose formed from amino acids or glycerol, which is included in net protein or lipid oxidation. In contrast, isotopic determination of glucose oxidation corresponds to oxidation of glucose originating from hepatic glycogen breakdown, of exogenously administered glucose, and of glucose formed from amino acids and glycerol. Non-oxidative glucose disposal, calculated as SGD-net CHOOX, corresponds to the sum of gluconeogenesis from amino acids or glycerol (which are included in net protein and lipid oxidation), glucose cycles, and glycogen synthesis. [less ▲]

Autorégulation de la production endogène de glucose

in Cahiers de Nutrition et de Diététique (1995)

Métabolisme hépatique du glucose après ingestion de fructose chez des sujets obèses non diabétiques et diabétiques non insulinodépendants

in Diabète & Métabolisme (1995), 21(suppl),

Effects of glucagon on fructose-induced alterations of glucose metabolism in man.

in Diabetes (1994), 44(suppl 1), 254

Effects of infused sodium lactate on glucose metabolism in healthy human.

in Diabetologia (1993), 36(suppl 1), 143