Hormonal interactions in carbohydrate metabolism.

Insulin is the key hormone of carbohydrate metabolism, it also influences the metabolism of fat and proteins. It lowers blood glucose by increasing glucose transport in muscle and adipose tissue and stimulates the synthesis of glycogen, fat, and protein. The anabolic action of insulin is antagonized by the catabolic action of glucagon. This hormone stimulates glycogenolysis and gluconeogenesis. The molar insulin: glucagon ratio is a parameter for an anabolic or a catabolic situation. Epinephrine also antagonizes insulin action. Like glucagon it stimulates glycogenolysis. In addition it reduces the insulin sensitivity of peripheral tissues and inhibits the release of insulin. Growth hormone decreases glucose uptake in muscle and adipose tissue gluconeogenesis in liver. In the presence of insulin, growth hormone stimulates protein synthesis. The net metabolic effects of a single hormone are directly related to the activity of other synergistic or antagonistic hormones.

Suitability of non-glucose-carbohydrates for parenteral nutrition.

Postoperative parenteral nutrition can only be optimally effective if the characteristics of post-traumatic metabolism are taken into account. Two main possibilities are discussed for the carbohydrate component of parenteral nutrition during this phase: glucose with high doses of insulin or non-glucose carbohydrates (sugar substitutes) possibly in a suitable combination with glucose. The risks as well as the technical and organisational problems involved in the use of them are discussed and the authors prefer the second of the two alternatives. Possible side effects of non-glucose carbohydrates are pointed out and it is shown how these can be avoided by observing dose guidelines. So far a combination of frucose : glucose : xylitol in a ratio of 2 : 1 :1 with a total dose of 0.50 g/kg/hour has been studied most thoroughly. This combination normalises the fat metabolism and improves glucose tolerance without requiring exogenous insulin. Experiences with this combination as well as individual non-glucose carbohydrates on operated patients have been given continuously for up to 7 days and in some cases even for several weeks. No side effects, no deviations from a steady state and no abnormal changes of the laboratory values occurred. The authors are of the opinion that non glucose carbohydrates are necessary if the facilities for frequent blood sugar controls are not available.

Interactions of insulin and epinephrine in human metabolism: their influence on carbohydrate and lipid oxidation rate.

Two groups of normal male subjects were given an infusion of insulin and an infusion of epinephrine + insulin respectively. Blood glucose, plasma free fatty acids (FFA), insulin, growth hormone, cortisol, and urinary catecholamines were determined. Continuous indirect calorimetry was used to measure metabolic rate and oxidation rates of carbohydrate and lipids. The first group (n equals 7) received a 30-minute insulin infusion (0.1 IU/kg). While blood glucose and plasma FFA decreased, carbohydrate oxidation and metabolic rate significantly increased after some delay, whereas lipid oxidation decreased. The increase in carbohydrate oxidation amounted to 5 g/120 min. The decrease in blood glucose during insulin administration did not correlate with the increase in carbohydrate oxidation. In the second group (n equals 7), a 150-minute epinephrine infusion (900 mug in 500 ml saline) was administered, and superimposed upon it, a similar insulin infusion initiated after 60 min. Epinephrine alone increased blood glucose and plasma FFA levels, and decreased insulinemia. The rise in the metabolic rate was sharp and significant. After a short but significant increase the oxidation rate of carbohydrate decreased, whereas that of lipids markedly rose. This increase significantly correlated with that in FFA. Addition of insulin markedly decreased the elevated FFA levels and lowered blood glucose. After some delay this was followed by a marked increase in carbohydrate oxidation and a decrease in lipid oxidation. In this test the total increase in carbohydrate oxidation was 11 g/120 min. In comparison with the insulin test, this double amount seems to correlate well with the higher blood glucose levels measured before insulin administration. The results suggest that insulin indirectly stimulates carbohydrate oxidation by facilitating glucose transport into the cells and lowering FFA levels, and that epinephrine favours lipid oxidation through its lipolytic effects and its suppression of insulin release.

Effects of oral xylitol administration on carbohydrate and lipid metabolism in normal subjects.

Oral tolerance tests with 30 and 50 g of xylitol were performed in 10 normal subjects adapted to taking this pentitol. A 50 g oral glucose tolerance test served as control. Continuous indirect calorimetry was carried out in 7 of these subjects to measure the effects on the metabolic rate and on the oxidation rates of carbohydrate and fat. A small and short rise in serum xylitol and low quantitites of xylitol excretion in urine were observed in both xylitol tests. Xylitol caused a small but statistically significant increase in blood glucose and plasma insulin concentrations. Plasma free glycerol diminished significantly. After xylitol the metabolic rate rose throughout the test period but the total increase was only half of that after glucose administration. There was no significant influence of xylitol on the oxidation rates of carbohydrate and lipids. The total increase in carbohydrate oxidation during 2 1/2 hours amounted to one fourth of that caused by glucose. It is suggested that xylitol, during the first two hours after ingestion, charges the body's metabolism much less than equal amounts of glucose. Therefore, the use of xylitol as a sweetener in the diet of diabetic patients seems to be justified.

[Measurement of carbohydrate oxidation by means of indirect continuous calorimetry in normal and diabetic subjects]. / Mesure de l'oxydation des glucides par calorimétrie indirecte continue chez des sujets normaux et diabétiques

The use of continuous indirect calorimetry in the course of a 100 g OGTT in 10 normal subjects has shown that carbohydrate oxidation rises with the secondary fall in blood glucose, suggesting that it could result from glucose stored under the influence of insulin. The experimental increase in FFA by a neutral fat infusion in 8 normal subjects decreased this oxidation in spite of the insulin rise. In a group of 5 non-obese, non-ketotic insulin-deficient diabetics, carbohydrate oxidation was found to be normal and directly correlated with plasma glucose levels. On the other hand, in 7 obese diabetics with high plasma insulin levels carbohydrate oxidation was found to be low, suggesting that carbohydrate intolerance could result from the non-oxidation of glucose. This study shows heterogeneity of diabetes, since glucose intolerance could result from non-oxidation of glucose as well as from insufficient pancreatic secretion.