James D. Best

Glucose Disposal is Not Proportional to Plasma Glucose Level in Man

Metabolic clearance rate (MCR) of glucose has been defined as the rate of glucose utilization divided by the glucose concentration. This model of glucose transport has been widely used as a measure of hormonally regulated glucose disposal, on the assumption that glucose disposal rate is proportional to glucose concentration. To test this assumption, the relationship between glucose concentration and disposal rate was studied in man during infusion of somatostatin ± exogenous insulin to achieve fixed plasma insulin levels of 1,18, and 46 μU/ml on separate days. When glucose concentration was increased to more than twice basal fasting levels, the glucose disposal rate increased significantly at all three insulin levels. However, the increase was not proportional to the rise in glucose concentration, and MCR fell by 38%, 16%, and 11% at the low, medium, and high insulin levels, respectively. These results are explained by an alternative model of glucose transport in which insulin-independent tissues such as brain have a relatively fixed glucose uptake, while other tissues have glucose transport systems which take up glucose at a rate proportional to its plasma concentration. We conclude that MCR of glucose is not a good measure of hormonally regulated glucose disposal because it is partially dependent on the glucose concentration, particularly at low insulin levels.

The Response of Plasma Triglyceride, Cholesterol, and Lipoprotein Lipase to Treatment in Non-insulin-dependent Diabetic Subjects Without Familial Hypertriglyceridemia

The effects of treatment on plasma total triglyceride, total cholesterol, and plasma postheparin lipase activities have not been evaluated in non-insulin-dependent diabetic (NIDD) subjects without a coexisting familial lipid disorder. In 49 untreated NIDD subjects, there was a linear relationship between glycosylated hemoglobin (GHb) and triglyceride (r = 0.35, P < 0.02). This correlation was improved after adjusting for the effects of obesity by a partial correlation analysis. After therapy, there was a significant relationship between the change in GHb and the change in triglyceride. To determine whether changes in lipid removal from plasma may contribute to the decrease in plasma lipid concentrations during treatment, the plasma postheparin lipoprotein lipase and hepatic lipase activities were evaluated in a subgroup (N = 8) of these NIDD subjects before and after 1 and 3 mo of therapy. Plasma postheparin hepatic lipase activity in the NIDD subjects was not different from that observed in six normal control subjects and did not change during therapy. In contrast, plasma postheparin lipoprotein lipase activity was lower in the untreated NIDD subjects than in the control subjects. Analysis of the two phases (early and late) of the postheparin lipoprotein lipase activity in plasma showed that the abnormal early phase in untreated NIDD corrected to normal values in less than a month, but the late phase was not corrected until the 3-mo measurement. These findings suggest that some NIDD subjects have a defect in heparin releasable lipoprotein lipase activity, which is reversed with improved glycemic control. This defect in lipoprotein lipase could contribute to the elevation in plasma triglyceride concentration by limiting triglyceride removal from plasma.

Hyperglycemia and beta-cell adaptation during prolonged somatostatin infusion with glucagon replacement in man.

To assess the relationship between β-cell function and the level and duration of hyperglycemia during generalized β-cell impairment, we studied the effects of acute and prolonged infusion of somatostatin in seven normal men. Twenty minutes after beginning an acute infusion of somatostatin (200 μg/h) plus glucagon replacement (0.75 ng/kg/min), plasma glucose (PG) remained unchanged, but plasma insulin (IRI) and acute insulin response to isoproterenol had fallen markedly. Seventy minutes after beginning somatostatin-plus-glucagon, a rise in PG was associated with an increase in the acute insulin response to isoproterenol, though not to the control level. In a separate study, after 46 h of the somatostatin-plus-glucagon infusion, at a glucose level similar to the 70-min level, plasma insulin had returned nearly to the control level and the acute insulin response to isoproterenol had returned completely to the control level. Such increases in basal and stimulated insulin secretion most likely represent a time-dependent adaptation by the β-cells to the persistent hyperglycemia. First- and second-phase insulin responses to intravenous glucose were markedly inhibited after 46 h of somatostatin-plus-glucagon. In summary, a 46-h infusion of somatostatin with glucagon replacement in humans leads to hyperglycemia, a slightly diminished basal insulin level, markedly decreased insulin responses to glucose, and an insulin response to isoproterenol maintained at a normal level by acute and probably chronic adaptation to the hyperglycemia. We speculate that β-cell adaptation to hyperglycemia may explain the similar abnormalities of islet function observed in patients with NIDDM.