Glucagon and insulin secretion in potential diabetes

Summary Insulin and glucagon have been studied in 20 subjects (both of the subjects’ parents were diabetic or in case of only one diabetic parent, the other showed a first degree familiarity of diabetes): 10 showed normal glucose tolerance (‘true prediabetics’) and 10 impaired glucose tolerance (‘genetic chemical diabetes’). Mean insulin response to oral (100 g) and i.v. glucose load (200 mg/kg followed by 20 mg/kg/min for 60 min) and to arginine infusion (25 g in 30 min) was normal in the prediabetics and delayed and higher in the subjects with chemical diabetes as compared to the control group. Glucagon response to arginine was higher, but not significantly, in prediabetics and in subjects with chemical diabetes. In both of these groups glucagon suppression by glucose was not observed. The insulin/glucagon molar ratio was significantly reduced after glucose infusion in these two groups. No correlation was found between insulin and glucagon secretion after arginine or glucose. A possible alteration in the mechanism controlling glucagon secretion even in the earliest phases of diabetes is suggested. This work was supported in part by C.N.R. (Consiglio Nazionale delle Ricerche), Roma, grant # CT 76.01345.04.     

Effect of the somatostatin analog D-Trp8,D-Cys14 on glucose insulin, pancreatic glucagon and growth hormone plasma levels in acromegalics and mild diabetics

The effect of the somatostatin analog (GHRIH-A) D-Trp8, D-Cys14 on plasma levels of growth hormone, pancreatic glucagon, insulin and glucose was studied in four acromegalic patients and in four maturity-onset mild diabetics. Acromegalics received a bolus iv injection of 25 microgram of GHRIH-A, followed by a continuous infusion of 25 microgram in saline over an hour. Mild diabetics were submitted in two different days to two tests: arginine (30 g in 30 min) +/- GHRIH-A (bolus iv injection of 25 microgram followed by an infusion of 25 microgram/h over 120 min) and arginine + saline. GHRIH-A lead to a significant (2 p less than 0.01) fall in GH basal secretion in acromegalics, and significantly reduced the GH response to arginine in maturity-onset diabetics. The inhibitory effect of insulin secretion was less impressive, but significative in both groups. No significant changes in plasma pancreatic glucagon values were noted. In mild diabetics, GHRIH-A infusion induced a small but significant increase in the blood glucose increment due to arginine. Our data suggest that this somatostatin analog may be potentially useful only when GH suppression is the main therapeutic goal to be reached, as in acromegaly and in severe diabetic retinopathy, but not in metabolic control of mild diabetic patients with a good residual insulin secretion.     

Beta-endorphin infusion restores acute insulin responses to glucose in type-2 diabetes mellitus

To address the possibility that an abnormality in pancreatic beta-endorphin activity might contribute to abnormal insulin secretion in diabetes mellitus, we studied the effects of beta-endorphin infusion on islet function in diabetic patients. The iv infusion of human beta-endorphin at a dose of 0.5 mg/h for 2 h in type-2 non-insulin-dependent diabetic patients (n = 12) raised plasma insulin and glucagon levels and slightly but significantly lowered plasma glucose concentrations. beta-Endorphin infusion also resulted in reappearance of a clear-cut acute insulin response to glucose, while second phase insulin release was increased and glucose disposal accelerated. Acute insulin and glucagon responses to arginine were not increased by beta-endorphin, suggesting that the effect of the opioid on the B cells of the diabetic patients is specific for glucose. An intraislet abnormality of opioid peptides action and/or secretion may play a role in the disturbances of insulin secretion in patients with type-2 diabetes mellitus.     

Comparative insulinogenic effects of glucose,arginine and glucagon in patients with diabetes mellitus,endocrine disorders and liver disease

Summary In order to compare the insulinogenic effects of glucose, arginine and glucagon, plasma immunoreactive insulin levels following oral glucose loading (50 g), intravenous arginine infusion (30 g for 45 min) and intravenous glucagon injection (1 mg) were determined in patients with diabetes mellitus, various endocrine diseases and chronic hepatitis. In patients with Cushing’s syndrome, plasma insulin responses to all three stimuli were exaggerated, whereas they were low in patients with pheochromocytoma. In other diseases, certain disparities were observed in plasma insulin responses. In patients with mild diabetes mellitus, insulin secretion elicited by glucose seems to be selectively impaired, because arginine and glucagon caused a rise in plasma insulin not significantly different from that in normal subjects. In patients with hyperthyroidism, plasma insulin responses to arginine and glucagon were either absent or limited, although rather a exaggerated response was noted following oral glucose loading. On the contrary, exaggerated responses to arginine and glucagon, and limited response to glucose were observed in hypothyroidism. In patients with chronic hepatitis, the responses of plasma insulin to glucose and arginine were both exaggerated, whereas the response to glucagon was comparable to that in normal subjects. These disparate responses suggest that glucose, arginine and glucagon act on the B-cell via different mechanisms.     

The mechanism of exaggerated glucagon response to arginine in diabetes mellitus

As far as exaggerated arginine-induced glucagon secretion in diabetics is concerned, the authors have shown that both the restoration of blood glucose excursions and physiological insulinemia in response to arginine, obtained from an artificial endocrine pancreas (AEP) could normalize the glucagon secretory responses in diabetes mellitus. To clarify whether or not physiological glycemic excursions and/or plasma insulin profiles contribute to the normalization of the exaggerated glucagon response in diabetes mellitus, the following 4 investigations were conducted on each of 7 non-obese, non-insulin-dependent diabetic (NIDDM), and 8 insulin-dependent diabetic (IDDM) subjects, with the aid of AEP. Arginine was i.v. infused into both diabetic groups (1) in a hyperglycemic state without insulin infusion, (2) in perfect glycemic control with insulin infusion by AEP, (3) in glycemic control with AEP, but with lower plasma insulin profiles (parameters of the insulin infusion algorithm were made smaller than those of (2], (4) in a state where blood glucose levels were clamped at the same levels as obtained in (1) with the aid of glucose infusion controlled by AEP, and where physiological plasma insulin profiles were mimicked by infusing insulin at the same rates used in (2) with a pre-programmable insulin infusion system. The changes in the plasma glucagon (IRG) response in each experiment were compared with those seen in healthy subjects. For both diabetic groups it was found that: in (2) perfect normalization of glucagon response was achieved.(ABSTRACT TRUNCATED AT 250 WORDS)     

Abnormal glucagon response to arginine and its normalization in obese hyperinsulinaemic patients with glucose intolerance: importance of insulin action on pancreatic Alpha cells

Summary An excessive glucagon secretion to intravenous arginine infusion was found in obese hyperinsulinaemic patients with glucose intolerance. This study was designed to determine whether the glucagon hyperresponsiveness to arginine in these patients would improve by insulin infused at a high enough dose to overcome insulin resistance. By infusing high dose insulin during arginine infusion, the previously exaggerated glucagon response to arginine could be normalized. To normalize the abnormal glucagon response, insulin doses of 4.2±0.7 and 3.8±0.5 IU were required during arginine infusion in obese hyperinsulinaemic patients with impaired glucose tolerance and Type 2 (non-insulin-dependent) diabetes mellitus, respectively. This achieved plasma peak insulin levels 3 to 4 times higher than those observed in non-obese healthy subjects. Furthermore, we clarified whether or not the effect of normalizing insulin action and/or glycaemic excursions contributed to normalizing the exaggerated glucagon response to arginine in these patients. Blood glucose was clamped while high dose insulin was infused at the same levels as observed during the arginine infusion test with no insulin infusion. As a result, normalization of the exaggerated plasma glucagon response was achieved, whether hyperglycaemia existed or not. These results clearly demonstrate that, similar to non-obese hypoinsulinaemic Type 1 (insulin-dependent) and Type 2 (non-insulin-dependent) diabetic patients, the exaggerated Alpha-cell response to arginine infusion in obese hyperinsulinaemic patients with glucose intolerance is secondary to the reduction of insulin action on the pancreatic Alpha cell, and that the expression of insulin action plays an important part in normalizing these abnormalities.     

Glucagon secretion in rats with non-insulin-dependent diabetes: an in vivo and in vitro study

Non-insulin-dependent diabetes ( NIDD ) was obtained in adult rats following a neonatal streptozotocin injection. Rats with NIDD exhibited a chronic low-insulin response to glucose in vivo, slightly elevated basal plasma glucose values (less than 2 g/l) and low pancreatic insulin stores (50% of the controls). Glucagon secretion was studied in this model, in vivo and in vitro using the isolated perfused pancreas technique. Normal basal plasma glucagon levels were observed in the fed state and were in accordance with normal basal glucagon release in vitro. The pancreatic glucagon stores were normal in the diabetics. In experiments with the perfused pancreas, the increased glucose concentration suppressed glucagon release as readily in the diabetics as in the controls. Moreover 5.5 mM glucose suppressed glucagon release stimulated by 19 mM arginine to the same extent in both groups. These data indicate that the suppression of A cell function by glucose is normal in rats with NIDD . Theophylline and isoproterenol also produced normal glucagon release in diabetics. By contrast, the glucagon secretion in response to arginine was lower in the diabetics. This was observed either in vivo (arginine infusion) or in vitro in the presence or the absence of glucose in the perfusate. But in the presence of theophylline the response to arginine was normalized in the diabetics. Impairment of A cell function of the diabetics is not limited to recognition of amino-acids, since acetylcholine evoked a lower glucagon response in the diabetics than in the controls. These defects are different from those described in their B cells.     

Beta-endorphin and islet hormone release in type-2 diabetes mellitus the effects of normoglycemia, enkephalin, naloxone and somatostatin

The present study was aimed at characterizing the effects of beta-endorphin on plasma glucose, insulin and glucagon plasma levels in subjects with type-2 diabetes mellitus. Infusion of 0.5 mg/h human beta-endorphin produced significant and simultaneous increments in both insulin and glucagon concentrations and decreased plasma glucose levels (-18 +/- 4 mg/dl, 60 min level, p less than 0.01). When the same diabetics were rendered euglycemic by an insulin infusion (1 mU/kg/min), beta-endorphin did not produce the expected decrease in plasma glucose concentrations nor raise plasma insulin levels; only the response of glucagon was preserved. Normal subjects were rendered hyperglycemic by an intravenous glucose infusion to match the plasma glucose levels of diabetic subjects. In this condition, beta-endorphin produced a significant increase of insulin concentrations, whereas glucagon remained suppressed. The intravenous administration of the long-acting met-enkephalin analogue DAMME (0.25 mg) blunted the hormonal responses to the subsequent beta-endorphin infusion in diabetic patients, although the inhibition was short-lived (30-40 min). Naloxone (5 mg), an opiate antagonist, did not produce any significant change in the insulin and glucagon responses to beta-endorphin, while somatostatin (0.25 mg/h) completely abolished the hormonal responses to the opioid.(ABSTRACT TRUNCATED AT 250 WORDS)     

The inhibitory effect of somatostatin on growth hormone, insulin and glucagon secretion in diabetes mellitus.

The inhibitory effect of somatostatin on insulin, glucagon and growth hormone secretion was studied in 5 patients with diabetes mellitus. In three maturity onset diabetics, somatostatin infusion abolished the insulin rise induced by breakfast and oral glucose, and in 2 of them, inhibited the basal insulin secretion by 50% seen during control studies. Concomitantly, there was a marked and prompt reduction of glucagon levels (50%) with a sustained effect. The plasma glucose levels were either unchanged or slightly increased. Following the somatostatin infusion, there was a prompt rebound increase in both insulin and glucagon levels with a relatively stable plasma glucose concentration. In contrast, a drastic reduction of plasma glucose in face of a relatively small fall in plasma glucagon in response to somatostatin infusion was observed in 2 insulin-dependent diabetics. In all patients, the episodic release of growth hormone seen during the control day was abolished during somatostatin infusion.     

Xylitol: stimulation of insulin and inhibition of glucagon responses to arginine in man.

The effect of intravenous xylitol infusions on plasma glucagon and insulin responses to intravenous arginine infusions (30 g for 45 min) or arginine "pulses" (4 g for 2 min) was studied in normal subjects. Intravenous infusion of arginine caused biphasic increases in plasma glucagon and insulin in all subjects studied. The increase in plasma glucagon induced by arginine infusion was significantly reduced by xylitol infusions started at 45 min before arginine infusion, irrespective of virtually unchanged blood glucose levels. Plasma insulin response to arginine was exaggerated by xylitol infusion.Repeated arginine pulses given at 30 min intervals evoked uniphasic and almost identical rises of plasma insulin and glucagon with each pulse. Intravenous xylitol infusions significantly blunted plasma glucagon responses and augumented the plasma insulin response to arginine pulses, despite only slight elevations of plasma glucose. These results suggest that xylitol has an inhibitory effect on both basal and arginine-stimulated glucagon secretion, while it enhances insulin secretion.     

Circulating insulin inhibits glucagon secretion induced by arginine in type 1 diabetes

OBJECTIVE: To evaluate if insulin has a suppressive effect on the glucagon secretion stimulated by arginine in type 1 diabetes. RESEARCH DESIGN AND METHODS: The alpha-cell response to an i.v. bolus of arginine (150mgkg(-1)) followed by an infusion of arginine (10mgkg(-1)min(-1)) was studied in random order during either low dose infusion (LDT) or high dose infusion (HDT) of insulin in ten patients with type 1 diabetes. The blood glucose level was clamped at an arterialized level of 5mmoll(-1) by a variable infusion of glucose. Venous C-peptide, glucagon, growth hormone, and insulin were analyzed. RESULTS: The mean plasma concentration of insulin was four times higher during the HDT. The C-peptide level did not differ between the LDT and the HDT. During the LDT in response to arginine the blood glucose level increased from 5.0 to 5.8mmol l(-1) although the glucose infusion was markedly reduced, while no change was seen during the HDT. A significantly smaller increase in the glucagon levels during the HDT was seen (area under the curve of 413+/-45 vs 466+/-44pgml(-1)h(-1), P=0.03) while the growth hormone levels were almost identical. CONCLUSION: This study demonstrates that a high level of circulating insulin exerts an inhibitory effect on the glucagon response to arginine in type 1 diabetes. Thus, the suppressive effect of insulin on the glucagon release from the alpha-cell seems to be general and not only dependent on stimulation by hypoglycemia.     

Uncontrolled diabetes mellitus and hyperglucagonemia associated with an islet cell carcinoma.

A 53 year old woman presented with diabetes mellitus, hyperglucagonemia (600 to 1,500 pg/ml), clinical hyperparathyroidism and an abdominal mass diagnosed on biopsy as an islet cell carcinoma. Glucagon content of the tumor was 0.78 mug/g wet weight. Hourly blood samples during a 24 hour period revealed a direct correlation between plasma glucose and glucagon. The oral administration of glucose paradoxically increased whereas the intravenous administration decreased plasma glucagon. Circulating glucagon levels were markedly increased with arginine and epinephrine infusion. Both short- and long-term administration of alpha adrenergic blockade depressed the glucagon response to epinephrine infusion. In contrast, long-term alpha adrenergic blockade increased glucagon secretion despite improved glucose tolerance during a second 24 hour study. Although the patient demonstrated overt clinical and chemical findings of hyperparathyroidism, parathyroid hormone (PTH) was not detected in her plasma. The pattern of tumor growth was consistent with an origin from pancreatic islets. We conclude that (1) the tumor was responsive to physiologic stimuli known to affect glucagon secretion; (2) elevations of plasma glucagon levels with oral and dietary glucose suggest regulation of secretion by intestinal factors; and (3) improvement of glucose tolerance with alpha adrenergic blockade may be related to increased insulin secretion.     

Loss of insulin response to glucose but not arginine during the development of autoimmune diabetes in BB/W rats: relationships to islet volume and glucose transport rate.

The insulin and glucagon responses to 10 mM glucose and 10 mM arginine were studied in pancreata isolated from nondiabetic diabetes-prone and diabetes-resistant BB/W rats at 60, 80, and 140 days of age and in diabetic BB/W rats on the 1st and 14th days of their diabetes. In the former group the insulin response to glucose declined progressively with age (r = -0.575; P less than 0.01) and at 140 days was significantly below age-matched diabetes-resistant controls (P less than 0.05). The insulin response to arginine did not decline with age in either group. For diabetic rats, on the first day of the diabetes, the insulin response to glucose was absent but the response to arginine did not differ from nondiabetic controls. On day 14 responses to glucose and arginine were both absent. The glucagon response to arginine showed no trend despite a decline in baseline glucagon secretion. Endocrine tissue in nondiabetic diabetes-prone rats made up 0.8 +/- 0.2% of the pancreas at 60 days of age and 0.52 +/- 0.22% at 140 days of age; the latter was significantly less than in 140-day-old diabetes-resistant controls (P less than 0.05). In diabetic rats on the 1st and 14th days of diabetes endocrine tissue was 0.2 +/- 0.1% and 0.07 +/- 0.02%, respectively. The glucose transport rate in islets isolated on the first day of diabetes was profoundly reduced compared to age-matched nondiabetic diabetes-prone controls. Thus, a population of arginine-responsive, glucose-unresponsive islets with low glucose transport rates is present at the onset of overt diabetes in BB/W rats.     

Effect of free fatty acids and amino acids on glucagon and insulin secretions in normal and diabetic ducks

Summary The relationship between two metabolites, free fatty acids (FFA) and amino acids (AA), and the two main pancreatic hormones, insulin and glucagon, was studied by infusing small amounts of these metabolites into normal and diabetic Peking ducks, i. e. two days after subtotal pancreatectomy. Infusion of oleic acid (0.365 g/kg/30 min as an emulsion in plasma) indicated a suppressive effect of free fatty acids on glucagon secretion, but was without effect on insulin secretion, in normal as well as in diabetic ducks, indicating that insulin might not be directly involved in the FFA-glucagon feedback in the duck. Infusions of arginine for one hour (1 g/kg/h) into normal ducks, hyperglycaemic normal birds (as a result of glucose infusion: 1 g/kg/h) and diabetic ducks, suggested the persistence of an amino acid effect on glucagon secretion, and a slight reduction of the effect on insulin secretion in diabetes. This suggests that insulin may not be involved in amino acidinduced glucagon secretion in the duck.     

Pancreatic hormone secretion in chronic pancreatitis without residual beta-cell function

Hormonal responses (glucagon, pancreatic polypeptide and somatostatin) to iv glucagon, iv arginine, and ingestion of a mixed meal were investigated in 6 patients with insulin-dependent diabetes secondary to chronic pancreatitis without beta-cell function, in 8 Type I (insulin-dependent) diabetics without beta-cell function, and 8 healthy subjects. No significant differences were found between the two diabetic groups regarding glucagon responses to arginine and meal ingestion. In the patients with diabetes secondary to chronic pancreatitis compared with Type I diabetics and normal controls, the pancreatic polypeptide concentrations were significantly lower and somatostatin concentrations were significantly higher after glucagon, arginine and a mixed meal. Thus, pancreatic glucagon secretion was preserved in patients with insulin-dependent diabetes secondary to chronic pancreatitis, having no residual beta-cell function. These findings suggest that pancreatic glucagon deficiency is not absolute in insulin-dependent diabetes secondary to chronic pancreatitis. A high level of somatostatin may contribute to a lower blood glucose level in patients with chronic pancreatitis.     

Mechanism of the blunted glucagon response to insulin-induced hypoglycemia in diabetics

It has been widely reported that dysfunctions of pancreatic A-cell occur in diabetics. Since these pancreatic A-cell dysfunctions are not normalized by conventional insulin injection treatment, they were thought to be a primary defect of diabetes mellitus. Recently it was found that paradoxic glucagon secretion to oral glucose and excessive glucagon response to i.v. arginine could be perfectly normalized if strict blood glucose regulations were achieved with appropriate insulin treatment. However, there has been no report on the perfect normalization of glucagon secretion in response to insulin-induced hypoglycemia in diabetics. In this report, to elucidate the precise significance of A-cell function in hypoglycemia in diabetics, the effect of long-term strict glycemic regulations and the importance of intact autonomic nerve function on hypoglycemia-induced glucagon secretion were studied. In experiments on hypoglycemia-induced glucagon secretion in diabetics, 0.2 to 0.3 U/kg of regular insulin injection were usually employed to overcome the hyperglycemia and insulin resistance. However, hyperinsulinemia has been demonstrated to suppress A-cell function in experiments using the euglycemic clamp technique. Therefore, the effect of plasma insulin concentrations after insulin injections was first studied in 7 healthy volunteers by injecting insulin at doses of 0.1 U/kg and 0.3 U/kg. In this experiment with 0.3 U/kg of insulin, the rate of fall in glycemia and the nadir of blood glucose were made similar to that with 0.1 U/kg of insulin by using glucose clamp technique with artificial endocrine pancreas. The plasma glucagon response after 0.3 U/kg of insulin was significantly suppressed as compared to that after 0.1 U/kg of insulin. From these experiments, it was concluded that not only hypoglycemic stimuli but also plasma insulin concentrations are important factors for demonstrating significant glucagon secretion in response to insulin-induced hypoglycemia. Second, the effects of strict glycemic control and autonomic nerve function on hypoglycemia-induced glucagon secretion were studied. Regular insulin at a dose of 0.1 U/kg was injected in an i.v. bolus form into 21 insulin-dependent (IDDM) and 22 noninsulin-dependent (NIDDM) diabetics before and one to three months after strict glycemic control with multiple insulin injection therapy or continuous subcutaneous insulin infusion therapy. To reduce fasting blood glucose level and to obtain the same hypoglycemic stimuli, overnight insulin infusion at a basal dose was undertaken in IDDM who showed hyperglycemia before strict glycemic regulations.(ABSTRACT TRUNCATED AT 400 WORDS)     

Glucagon dose-response curve for hepatic glucose production and glucose disposal in type 2 diabetic patients and normal individuals

This study sought to examine whether enhanced hepatic sensitivity to glucagon contributes to impaired glucose homeostasis in subjects with type 2 diabetes mellitus (T2DM). Eight T2DM and 9 age-, weight-, and gender-matched nondiabetic subjects received a 4-hour glucagon infusion at the rates of 0.2, 0.5, 2, 6, and 8 ng. kg(-1). min(-1) while maintaining the plasma insulin concentration constant at the basal level with exogenous infusions of somatostatin and insulin. On the evening prior to study, diabetic subjects received a low-dose insulin infusion at a rate designed to maintain euglycemia and this infusion rate was continued until the end of the glucagon infusion study on the following day. Each glucagon infusion study was performed on a separate day and in random order. 3-(3)H-glucose was infused in all studies to measure endogenous glucose production (EGP) and the rate of whole body glucose disposal. During the first 2 hours (0 to 120 minutes) of glucagon infusion, EGP increased sharply in both groups, and the initial rate of rise in EGP was higher in control versus diabetic subjects. During the last 2 hours (120 to 240 minutes) of glucagon infusion, EGP in the diabetics tended to be higher than controls during the 3 lower glucagon infusion rates and this difference reached statistical significance (P <.05 to.01) during the 6 and 8 ng. kg(-1). min(-1) infusions. During the 2 hours following cessation of glucagon (240- to 360-minute time period), the stimulation of glucose disappearance from plasma was impaired (P <.05) during all 5 glucagon infusion rates in the diabetics compared to controls. We conclude that in T2DM patients, the initial (0 to 120 minutes) stimulation of hepatic glucose output (which primarily reflects glycogenolysis) by glucagon is not enhanced in T2DM patients. The late (120 to 240 minutes) stimulation of hepatic glucose output (which primarily reflects gluconeogenesis) by glucagon tends to be increased, especially at supraphysiologic plasma glucagon concentrations.     

Secondary failure of oral hypoglycaemic agents in lean patients with type 2 diabetes mellitus: insulin sensitivity, insulin response to different stimuli, and the role of cyclic-AMP.

The aim of this study was to evaluate the insulin (IRI) response to different stimuli and insulin sensitivity in Type 2 diabetic patients responsive to oral hypoglycaemic agents (OHA) and in Type 2 diabetic patients with secondary failure of OHA (SF), all patients being of normal body weight (relative body weight less than 120%), and the possible role of cyclic AMP in the reduced IRI release. SF patients, without islet cell antibodies (ICA), with hyperglycaemia lasting more than 3 months, underwent tests with i.v. tolbutamide (n = 21), i.v. glucose (n = 14), i.v. glucagon (n = 19), i.v. arginine infusion (n = 18); the arginine infusion was repeated in 12 patients during administration of aminophylline, an inhibitor of phosphodiesterase. The same tests were performed in groups of 8 to 15 OHA patients and in groups of 6 to 17 healthy subjects. During all the tests, blood glucose levels were higher in SF patients, than in OHA patients and in healthy subjects. Both SF patients and OHA patients had no IRI response to glucose; SF patients, in contrast to OHA patients, had a reduced IRI response to tolbutamide and to glucagon. The IRI response to arginine was not different in OHA, in SF patients and in healthy controls, but was significantly enhanced by aminophylline only in healthy controls. Insulin infusions (1.66 mU/Kg/min for 90 min) were performed in OHA patients and in SF patients at blood glucose levels of 150 and of 250 mg/dl: during the last 60 min, the amount of glucose metabolized (M), and the insulin sensitivity (M/I) index were greater in OHA than in SF patients.(ABSTRACT TRUNCATED AT 250 WORDS)     

Dose-kinetics of pancreatic glucagon responses to arginine and glucose in subjects with normal and impaired pancreatic B cell function

Summary Pancreatic glucagon responses to different amounts of intravenous arginine and glucose were studied in 10 insulin-dependent diabetics, 14 healthy controls (high insulin responders) and 15 subjects with decreased insulin response to glucose but normal intravenous glucose tolerance (low insulin responders). The dose-kinetics of the glucagon response was studied by using four different arginine doses. The suppressive effect of glucose was evaluated by infusing three glucose doses during a submaximal stimulation with arginine. The diabetics were tested first when under fair metabolic control and then following intensive treatment with insulin to produce near-normalisation of blood glucose. Finally, five subjects underwent insulin-induced hypoglycaemia. The changes in plasma glucagon and blood -amino-nitrogen in response to the four arginine doses were significantly correlated in all groups but the slope of the dose response curve was steeper in the poorly controlled-diabetics than in the non-diabetics. These diabetics displayed higher fasting plasma glucagon values than healthy controls (high insulin responders) (224±4 versus 151±22 pg/ml, p<0.01), higher plasma glucagon responses to arginine and an absence of inhibition by glucose of the arginine-stimulated glucagon release. In strictly controlled diabetic patients, fasting plasma glucagon levels (176±16 pg/ml) were not significantly different from healthy controls, the glucagon response to arginine returned to the normal range, A cell suppressibility by glucose was restored and A cell stimulation by hypoglycaemia reappeared. In the low insulin responders, fasting plasma glucagon was not different from that of high responders (107±12 pg/ml), the slope of the dose response curve to arginine was similar in both groups and the A cells were inhibited by glucose to a similar extent. These results support the concept that islet A cell dysfunction in diabetes is not a primary phenomenon.     

Gastric inhibitory polypeptide response to hyper- and hypoglycemia in insulin-dependent diabetics.

The response of gastric inhibitory polypeptide (GIP) levels to oral glucose in 11 insulin-dependent diabetics was compared to that in 8 age- and sex-matched healthy controls to determine whether they would show the pattern of GIP hypersecretion reported by other workers in maturity-onset, insulin-independent diabetes. One gram of glucose per kg bw resulted in a higher level of glycemia and a significantly diminished GIP response in diabetics when compared to controls (6,018 +/- 1,337 vs. 11,343 +/- 2,353 pg/ml.180 min min, respectively). There was virtually no beta cell response in the diabetics, as measured by changes in the levels of free insulin and connecting peptide. A significant lowering of glucagon levels occurred in the controls, while an inconsistent response was seen in the diabetics. An insulin infusion test was administered to test the hypothesis that insulin suppresses GIP secretion. Although hyperinsulinism, hypoglycemia, and suppression of endogenous insulin secretion were produced in the controls, no suppression of baseline GIP was detected. Similarly, hyperinsulinism and hypoglycemia failed to suppress baseline GIP levels in the diabetics. These results do not support a direct role for insulin in suppressing GIP in normal or diabetic subjects.