Glucose-dose dependent characteristics of insulin secretion in obese and lean sheep

We previously reported that obesity in sheep and cattle was associated with basal hyperinsulinemia, insulin resistance, and an exaggerated insulin response to a single dose (350 mg/kg) of glucose. In this study, the glucose-dose dependency of insulin secretion in obese and lean sheep was determined by 1) using jugular venous concentrations of insulin (Exp 1) and 2) arteriovenous differences in insulin concentrations across the pancreas together with plasma flow rates in the portal vein (Exp 2). Sheep were injected with glucose doses of 0 (water), 10, 30, 100, and 350 mg glucose/kg body weight in Exp 1 (six sheep per group) and with a low (20 mg/kg) and high (200 mg/kg) dose of glucose in exp 2 (four sheep per group). In Exp 1, mean (+/- SE) pretreatment plasma concentrations of insulin (22.0 +/- 1.7 vs. 9.4 +/- 0.4 microU/ml) and glucose (56.1 +/- 0.5 vs. 52.4 +/- 0.8 mg/dl) were greater (P less than 0.01) in obese than lean sheep fasted for 12 h. The glucose-induced rises in insulin concentrations above pretreatment levels were always greater (P less than 0.05) in obese than lean sheep regardless of glucose dose. Eadie-Scatchard plot analysis of the hyperbolic relationship between the acute insulin and acute glucose response areas (0 to +10 min) indicated that the maximum (Vmax) early phase insulin response was greater (P less than 0.025) in obese than lean sheep (568 +/- 148 vs. 156 +/- 33 microU ml-1 X min). In Exp 2, pretreatment concentrations of insulin (25.1 +/- 3.4 vs. 5.6 +/- 1.2 microU/ml) and glucose (58.3 +/- 1.8 vs. 45.5 +/- 1.1 mg/dl) in arterial plasma were greater (P less than 0.01) in obese than in lean sheep fasted 18 to 22 h. Similarly, pretreatment pancreatic secretion rates of insulin were greater (P less than 0.01) in obese (17.8 +/- 5.8 mU/min) than in lean (4.9 +/- 1.3 mU/min) sheep. Glucose-induced acute (0 to +10 min) increments in pancreatic secretory rates of insulin also were greater (P less than 0.05) in obese than in lean sheep after the low (215 +/- 73 vs. 11 +/- 15 mU) and high (881 +/- 281 vs. 232 +/- 66 mU) doses of glucose. It was concluded that insulin secretion in response to a range of stimulatory concentrations of glucose was greater in obese than in lean sheep because the obese sheep had greater maximum (i.e. Vmax) acute phases of glucose-induced insulin secretion.     

Diazoxide infusion at excess but not at basal hyperglycemia enhances beta-cell sensitivity to glucose in vitro in neonatally streptozotocin-diabetic rats.

The influence of chronic and moderate hyperglycemia vis-à-vis a 48-hour further elevation of blood glucose on beta-cell sensitivity to glucose was compared in an animal model of non-insulin-dependent diabetes. Neonatally streptozotocin-diabetic (n-STZ) rats infused with saline for 48 hours displayed moderate nonfasting hyperglycemia (mean, 11.5 +/- 1.5 mmol/L/48 h) and plasma insulin levels similar to those seen in normoglycemic, nondiabetic rats. In perfused pancreas, the insulin response to 27 mmol/L glucose was severely reduced to 1.60 +/- 0.45 pmol/min, ie, approximately 15% of the response in nondiabetic rats. A continuous infusion of diazoxide (5 mg/kg/h), which normally blocks glucose-induced insulin secretion, did not affect glucose and insulin levels in vivo, nor did it significantly affect the insulin response to glucose in vitro. In other experiments, "basal" hyperglycemia in n-STZ rats was doubled by glucose infusions for 48 hours to reach a mean of 23.8 +/- 0.6 mmol/L. Plasma insulin increased 3.2-fold. The in vitro insulin response to 27 mmol/L glucose was totally abolished, and the pancreatic insulin content was decreased by 81% relative to the content after saline. Addition of a diazoxide infusion inhibited the increase in plasma insulin by 93%. After the combined glucose and diazoxide infusion, the subsequent in vitro response to 27 mmol/L glucose was dramatically enhanced to 9.55 +/- 3.25 pmol/min, ie, the response was sixfold higher than after saline alone. This aftereffect of the diazoxide infusion was not significantly altered by an insulin infusion (2 U/d) added to the hyperglycemia plus diazoxide protocol to compensate for the insulin-lowering effect of the drug.(ABSTRACT TRUNCATED AT 250 WORDS)     

Differential effects of prolonged hyperglycemia on in vivo and in vitro insulin secretion in rats

The purpose of this study was to investigate the effects of a 48-h glucose (30% wt/vol) infusion in unrestrained catheterized healthy rats (HG) on subsequent in vivo and in vitro insulin response to glucose. High hyperglycemia (400-450 mg/dl) and resulting hyperinsulinemia (1.2 +/- 0.1 mU/ml vs. 0.15 +/- 0.03 mU/ml in controls) were maintained throughout the infusion period. Glucose-induced insulin secretion was examined in vivo 3 h after the end of infusion by performing either a glucose tolerance test or a hyperglycemic clamp (225 mg/dl for 60 min). In addition, in vivo insulin secretion was studied on day 1, 3, 5, and 7 after the end of glucose infusion by performing glucose tolerance tests. Insulin secretion was also investigated in vitro, using the isolated perfused pancreas technique, 3 h and 1 day post glucose infusion. During glucose tolerance tests and hyperglycemic clamps performed at 3 h, insulin secretion was much greater in HG rats than in controls, and remained increased until day 5. By contrast, when studied in vitro 3 h after the end of the infusion, glucose-induced insulin release from isolated perfused pancreases was impaired in HG rats as compared with controls, and the insulin response to arginine was dramatically increased. However, insulin secretion in vitro returned partially to normal after day 1. These data indicate that prolonged hyperglycemia has quite different effects on the subsequent insulin secretion in vivo or in vitro. It impairs, but reversibly, glucose-induced insulin secretion in vitro, whereas it increases it durably in vivo. This suggests that humoral and/or nervous interferences can counterbalance the possible perturbing effects of prolonged hyperglycemia on the normal B cell responsiveness to glucose.     

Gliclazide at a lower concentration than therapeutic dose increases the sensitivity of insulin secretion to glucose in perfused rat pancreas

OBJECTIVES: We studied the difference between effects of therapeutic dose and sub-therapeutic dose of gliclazide on the glucose-induced insulin secretion. METHODS: The normal rat pancreas was isolated and perfused with Krebs-Ringer buffer containing 1-14 mmol/l glucose. Influcences of 0.25 and 2.5 microg/ml gliclazide on the glucose concentration-insulin secretion curve was examined. RESULTS: Gliclazide at 0.25 microg/ml significantly potentiated 5-8 mmol/l glucose-induced insulin secretion (2.5 +/- 0.5 vs 1.0 +/- 0.3 mU for 15 min at 6.5 mmol/l glucose, P<0.01), but did not give influence on either 1-3 or 10-14 mmol/l glucose-induced insulin secretion. The glucose concentration, at which half-maximal insulin secretion was observed, was lower with gliclazide (5.9 mmol/l) than in the control (7.5 mmol/l). Gliclazide at 2.5 microg/ml markedly increased the maximally glucose-stimulated insulin secretion from 3.9 +/- 0.5 mU for 15 min in the control to 6.6 +/- 0.7 mU for 15 min (P<0.01). The half-maximal insulin secretion was observed at a lower glucose concentration (5.0 mmol/l) than in the absence of gliclazide. CONCLUSION: Gliclazide in sub-therapeutically low dose has different effects on insulin secretion from in therapeutic dose, namely sharpens the insulin secretion sensitivity to glucose with no influence on the maximal insulin secretion. It is possible that low doses of gliclazide might be of interest in some type 2 diabetics whose main pathophysiology is the blunting of insulin secretion response to hyperglycemia.     

Physiological concentrations of growth hormone exert insulin-like and insulin antagonistic effects on both hepatic and extrahepatic tissues in man

To determine whether increments in circulating GH concentrations within the physiological range would exert insulin-like as well as insulin-antagonistic actions in man and, if so, whether both actions would occur in hepatic and extrahepatic tissues, normal volunteers (n = 6) were infused with human GH (hGH; 100 ng/kg . min) for 6 h along with somatostatin (100 micrograms/h) to suppress insulin, glucagon, and hGH secretion and also with sufficient insulin (100 microU/kg . min) to maintain a constant plasma insulin level. During the final 2 h, glucose (2 mg/kg . min) was infused. In control studies, saline was infused instead of hGH. Infusion of hGH increased plasma hGH to 35 ng/ml. Plasma glucose decreased to 60 +/- 2 mg/dl compared to 67 +/- 1 mg/dl observed in control studies (P less than 0.05); this greater hypoglycemia was due to both greater suppression of hepatic glucose production (P less than 0.05) and greater augmentation of glucose clearance (P less than 0.05). These insulin-like effects of hGH were no longer evident after 2 h. Subsequently, when glucose was infused, plasma glucose increased to 133 +/- 4 mg/dl compared to the 104 +/- 6 mg/dl observed in control studies (P less than 0.01). This greater hyperglycemia was due to both impaired suppression of hepatic glucose production (P less than 0.001) and decreased glucose clearance (P less than 0.01). These results indicate that physiological increments in plasma hGH cause both insulin-like and insulin-antagonistic effects in man and that these actions occur in hepatic as well as extrahepatic tissues. The insulin-like actions of hGH are transient.     

Chronic in vivo hyperglycemia impairs phosphoinositide hydrolysis and insulin release in isolated perifused rat islets

We examined the effect of chronic hyperglycemia on phosphoinositide hydrolysis and insulin secretion in isolated perifused rat islets. Rats were infused for 44 h with 40% dextrose in order to raise and maintain the plasma glucose concentration at 350 mg/dl. Control animals were infused with equiosmolar amounts of mannitol. In vivo insulin secretion and rats of glucose disposal were monitored throughout the study. At the end of the infusion, islets were collagenase isolated, and phosphoinositide (PI) hydrolysis (assessed by measuring the increment in [3H]inositol efflux as well as labeled inositol phosphates) and insulin output in response to a 20-mM glucose challenge were quantitated. Plasma insulin concentration and in vivo glucose disposal rates decreased significantly, by 47% and 35% respectively, after 6-8 h of hyperglycemia. In islets perifused immediately after isolation, prior in vivo hyperglycemia markedly altered the pattern of insulin output in response to 20-mM glucose challenge. Compared to mannitol infusion, 20 mM glucose stimulation resulted in an exaggerated first phase insulin secretory response (1121 +/- 88 vs. 467 +/- 75 pg/islets.min) and a blunted second phase insulin secretory response (392 +/- 90 vs. 1249 +/- 205 pg/islet.min). In islets prelabeled with myo-[2-3H]inositol for 2 h, PI hydrolysis, particularly [3H]inositol efflux in response to glucose stimulation was also reduced (0.28 +/- 0.03%/min) compared to that in mannitol-infused animals (0.53 +/- 0.08%/min). Two hours of preincubation in a low glucose medium (2.75 mM) were able to completely reverse the islet defect in both PI hydrolysis and insulin secretion. Our results demonstrate that chronic in vivo hyperglycemia impairs PI hydrolysis in perifused rat islets and suggest that this defect accounts in part for the abnormal pattern of glucose-induced insulin secretion.     

Effect of acute hyperglycemia on plasma triglyceride concentration and triglyceride secretion rate in non-fasted rats

The effect of an intravenous infusion of glucose on plasma triglyceride (TG) concentration in fed rats was determined in order to partially elucidate the mechanism of diabetes-induced hypertriglyceridemia. Glucose infused at 8 mg/kg per min caused the plasma TG concentration to be elevated significantly when compared to controls infused with saline alone. In rats which were euglycemic (clamped, insulin infused at 2.5 mU/kg per min), plasma TG concentration remained constant throughout the glucose infusion period (8 mg/kg per min). Hyperglycemic rats infused with insulin (2.5 mU/kg per min) as well as with glucose (16 mg/kg per min) were also hypertriglyceridemic. Infusion of insulin alone did not change the concentration of plasma TG over a 150 min period. Glucose was also infused (8 mg/kg per min) with somatostatin (1 micrograms/kg per min) to block endogenous production of insulin. Somatostatin infusion did not suppress glucose-induced hypertriglyceridemia. For all treatments, the net change in TG concentration was found to positively correlate with the net change in plasma glucose concentration at 150 min after the infusions (r = 0.83, P less than 0.001). The higher TG concentration in the glucose infused, hyperglycemic clamp and glucose plus somatostatin groups reflected an increased rate of TG secretion, in the presence of a lower concentration of plasma free fatty acids. These results suggest that in a non-fasted state, acute hyperglycemia increases plasma TG by stimulating hepatic TG secretion, in a manner which is independent of either plasma insulin or free fatty acids levels.     

Effect of free fatty acids on glucose uptake and nonoxidative glycolysis across human forearm tissues in the basal state and during insulin stimulation

We tested whether FFAs influence glucose uptake by human peripheral tissues in vivo. Whole body glucose uptake, FFA turnover, energy expenditure and substrate oxidation rates, forearm glucose and FFA uptake, and nonoxidative glycolysis (net release of alanine and lactate) were measured in 14 normal male subjects in the basal state (0-240 min; serum insulin, approximately 5 microU/mL) and during euglycemic hyperinsulinemia (240-360 min; approximately 75 microU/mL) on 2 separate occasions, once during elevation of plasma FFA by infusions of Intralipid and heparin (plasma FFA, 4.6 +/- 0.1 vs. 4.2 +/- 0.4 mmol/L; 180-240 vs. 300-360 min) and once during infusion of saline (plasma FFA, 0.50 +/- 0.07 vs. 0.02 +/- 0.07 mmol/L, respectively). In the basal state, whole body glucose disposal remained unchanged, but the fate of glucose was significantly altered toward diminished oxidation (7.3 +/- 0.8 vs. 5.6 +/- 0.5 mumol/kg.min; P less than 0.05, saline vs. Intralipid) and increased nonoxidative glycolysis (P less than 0.05). Elevation of plasma FFA significantly increased forearm glucose uptake (1.0 +/- 0.6 vs. 2.4 +/- 0.7 mumol/kg.min; P less than 0.01) and nonoxidative glycolysis (net release of alanine and lactate, 0.4 +/- 0.5 vs. 1.2 +/- 0.4 mumol glucose equivalents/kg.min; P less than 0.05). During hyperinsulinemia, FFA decreased whole body glucose disposal (38 +/- 2 vs. 30 +/- 3 mumol/kg.min; P less than 0.001) due to a decrease in glucose oxidation (13 +/- 1 vs. 7 +/- 1 mumol/kg.min; P less than 0.01, saline vs. Intralipid), and forearm glucose uptake (31 +/- 4 vs. 24 +/- 6 mumol/kg.min; P less than 0.01, saline vs. Intralipid). Under these conditions, 7 +/- 2% and 3 +/- 1% (P less than 0.05) of forearm glucose uptake could be accounted for by nonoxidative glycolysis in the Intralipid and saline studies, respectively. In summary, 1) elevation of plasma FFA concentrations suppresses the rate of carbohydrate oxidation to a rate that, both basally and during hyperinsulinemia, is similar to that reported for insulin-independent glucose oxidation in the brain; 2) basally, forearm glucose uptake is increased by FFA; and 3) during hyperinsulinemia, FFA inhibit glucose uptake by forearm tissues. We conclude that the interaction between glucose and FFA fuels in human forearm tissues is dependent upon the ambient insulin concentration; the increase in basal glucose uptake would be compatible with the increase need of glucose for FFA reesterification; the decrease in insulin-stimulated glucose uptake supports operation of the glucose-FFA cycle in human forearm tissues.     

Importance of substrate competition in the mechanism of insulin resistance in man

Carbohydrate (CHO) oxidation induced by a glucose or fructose (0.5 g/kg X h) infusion over two hours was compared for 160 minutes by means of continuous indirect calorimetry in seven normal subjects without or with a concomitant infusion of Intralipid, a neutral fat emulsion. The glucose infusion was accompanied by a rise over basal values in both glucose (99 +/- 10 mg/dL) and insulin (36 +/- 7 microU/mL) plasma levels, with a further rise of both curves during the Intralipid infusion (140 +/- 7 mg/dL and 53 +/- 12 microU/mL). By contrast, plasma glucose and insulin rose only minimally during the fructose infusion (3.5 +/- 2.9 mg/dL and 5.3 +/- 1.4 microU/mL, respectively, without Intralipid, and 10.6 +/- 2.1 mg/dL and 9.6 +/- 2.0 microU/mL with Intralipid). During the two-hour sugar infusion, a mean quantity of 68.7 g glucose or fructose was infused. The total CHO oxidation was 15.6 +/- 1.2 g for glucose and 21.6 +/- 2.6 for fructose infusion for the 160 minutes of the test. During the Intralipid infusion, CHO oxidation was inhibited with values of 5.9 +/- 1.3 g for glucose (P less than .005) and 13.8 +/- 1.8 g (P less than .05) for fructose infusion. Lipid oxidation was increased in both cases during the Intralipid infusion. These results show that the lipid-induced inhibition of CHO oxidation observed with glucose infusion also occurs to some extent with fructose, suggesting that insulin might not be primarily involved. They suggest a metabolic origin for insulin resistance during elevated fat metabolism.     

Interaction between epinephrine, prostaglandin E, and met-enkephalin in the regulation of insulin release in man

Prostaglandin E (PGE), epinephrine and metenkephalin are three endogenous substances normally present in the endocrine pancreas which have been reported to inhibit glucose-induced insulin secretion in normal humans. To evaluate possible synergistic interactions between these inhibitory agents upon the regulation of insulin release in man, we examined the effects of PGE, epinephrine and the long-acting met-enkephalin analogue FK 33-824, given alone or in combination, upon glucose-induced insulin secretion in normal man. The infusion of the three agents at doses known to affect insulin secretion (10 micrograms/min, 15 ng/kg/min, 0.5 mg im, respectively) produced the expected inhibitory effects upon insulin responses to an intravenous glucose challenge. The infusion of the three agents at doses which did not produce per se any significant change of insulin responses to glucose (5 micrograms/min, 5 ng/kg/min, 0.2 mg i.m., respectively), caused a significant inhibition of this response when given in combination. In particular, the acute insulin response to glucose decreased from a control value of 50 +/- 9 microU/ml to a value of 21 +/- 6 microU/ml (p less than 0.02). The inhibitory effect of epinephrine (15 ng/kg/min) upon glucose-induced insulin secretion was partially reversed by sodium salicylate, an inhibitor of endogenous prostaglandin synthesis, which increased but not normalized, either the acute insulin response and the glucose disappearance rates. Similarly, the negative effect of FK 33-824 upon glucose-induced insulin secretion was reversed by sodium salicylate. Similar findings were also obtained with indomethacin, another structurally unrelated inhibitor of endogenous prostaglandin synthesis.(ABSTRACT TRUNCATED AT 250 WORDS)     

Metabolic control during total parenteral nutrition: use of an artificial endocrine pancreas

The metabolic impact of total parenteral nutrition (TPN) was evaluated in nine subjects who underwent esophagogastroplasty for esophageal carcinoma. On the second day after operation all subjects were connected to an artificial endocrine pancreas. In four patients only glucose was infused (5.5 mg/kg X min). The remaining five subjects received glucose (4.0 mg/kg X min), amino acid (0.5 mg/kg X min), and lipid emulsion (0.6 mg/kg X min). Plasma glucose concentration was kept constant over 24 hours. However, both insulin requirement (111 +/- 15 v 70 +/- 2 mU/kg X h) and plasma insulin level (99 +/- 15 v 30 +/- 7 microU/mL; P less than .01) were higher during combined TPN. Blood lactate concentration was higher during glucose infusion (P less than .05). No difference was found in blood concentrations of pyruvate, alanine, and ketone bodies. Both glycerol and FFA were higher during combined TPN. The ratio between glucose infusion rate and the average plasma insulin level was calculated as an index of insulin-mediated glucose metabolism; G/I X 100 was markedly reduced during combined TPN (4.5 +/- 0.8 v 20.7 +/- 3.7; P less than .05). Plasma FFA levels were positively correlated with plasma insulin concentration (r = .76) and inversely correlated to G/I X 100 (r = -.73; both P less than .05). In conclusion, during combined TPN a state of insulin resistance is induced and more insulin is required to achieve a normal glucose utilization.     

Oxytocin stimulates glucagon and insulin secretion in fetal and neonatal sheep

In adults of several species arginine vasopressin (AVP) and oxytocin (OT) stimulate pancreatic secretion of immunoreactive plasma glucagon (IRG). In fetal sheep AVP is an important stress hormone and may be simultaneously secreted with OT; however, their effects on IRG secretion are not known. We sought to determine if AVP and/or OT affected pancreatic IRG secretion in fetal and neonatal sheep. Either AVP or OT was infused for 30 min in chronically catheterized fetal and neonatal sheep, obtaining peripheral arterial and/or portal venous blood samples before; 10, 15, and 30 min during; and 15, 30, and 60 min after infusion for measurements of blood gases, hematocrit, IRG, immunoreactive plasma insulin (IRI) and plasma glucose. AVP did not affect IRG or IRI in fetal sheep (mean +/- SE, 133 +/- 1 days gestation), but small increases occurred in portal venous blood of lambs (2-49 days old). In contrast, OT (4.6 +/- 0.3 mU/min.kg; n = 12) increased fetal plasma IRG from 72 +/- 5 to 86 +/- 6 and 97 +/- 7 pg/ml (P less than 0.001) and IRI from 16 +/- 2 to 20 +/- 3 and 20 +/- 2 microU/ml (P less than 0.02) at 15 and 30 min, respectively; 157 +/- 11 microU OT/min.kg had no effect. In lambs (2-49 days old), 3.0 mU OT/min.kg increased arterial (n = 15) IRG from 139 +/- 19 to 367 +/- 43 and 483 +/- 76 pg/ml (P less than 0.01) and portal IRG (n = 8) from 167 +/- 39 to 341 +/- 72 and 502 +/- 148 pg/ml (P less than 0.01), respectively. Arterial and portal IRI also rose (P less than 0.01) from 36 +/- 4 to 82 +/- 12 and 105 +/- 32 microU/ml and from 29 +/- 5 to 65 +/- 13 and 51 +/- 7 microU/ml, respectively. Glucose was unchanged in all experiments. In fetal and neonatal sheep, AVP has minimal effects on IRG and IRI release. In contrast, OT increases both substantially; furthermore, there is a difference in fetal and neonatal responsiveness. OT may be important in modulating glucagon and insulin secretion during and after parturition.     

The physiologic action of insulin on glucose uptake and its relevance to the interpretation of the metabolic clearance rate of glucose

Glucose uptake (Ru) is dependent upon the concentrations of both glucose and insulin. The metabolic clearance rate of glucose (MCRG), has been used as an in vivo measure of insulin action, because it was said to be independent of the prevailing glucose concentration. The validity of this assumption has recently been challenged. In this study, the effect of insulin concentration on the rate of glucose uptake (Ru) and on the MCRG was studied during euglycemia (5.1 +/- 0.3 mmol/L) and moderate hyperglycemia (10.4 +/- 0.5 mmol/L) in 17 experiments on nine normal ambulant volunteers. Stable plasma insulin levels were maintained with fixed infusion rates of insulin (0-300 mU/kg/h) and somatostatin (7.5 micrograms/min). At low insulin concentrations (less than 5 microU/mL) the increase in glucose uptake in response to hyperglycemia was small (5.3 +/- 2.3 mumol/kg/min). In contrast, with insulin levels more than 25 microU/mL, there was a steep rise in glucose uptake with hyperglycemia (55 +/- 3 mumol/kg/min; range: 44-74 mumol/kg/min). The metabolic clearance rate of glucose fell by an average of 32% with hyperglycemia in the studies at the lowest insulin levels (2.2 +/- 0.6 v 1.5 +/- 0.1 mL/kg/min; 0.15 greater than P greater than 0.1). There was no change in the MCRG in the subjects studied at higher insulin levels. It is concluded that (1) low concentrations of insulin are essential for the increase in glucose disposal during hyperglycemia; and (2) provided insulin levels are more than 25 microU/mL and plasma glucose less than 11 mmol/L, MCRG is independent of the plasma glucose concentration and is therefore a valid measure of insulin-mediated glucose uptake.     

Modulation of insulin secretion by insulin and glucose in type II diabetes mellitus

We studied the dose-response characteristics of insulin's ability to modulate its own secretion in normal and type II diabetic (NIDDM) subjects by measuring suppression of serum C-peptide levels during insulin infusions with the plasma glucose level held constant. In normal subjects at euglycemia, primed continuous insulin infusion rates of 15, 40, 120, and 240 mU/M2 X min acutely raised serum insulin to steady state levels of 37 +/- 2 (+/- SE), 96 +/- 6, 286 +/- 17, and 871 +/- 93 microU/ml, respectively. During each infusion, maximal suppression of C-peptide to 30% of basal levels occurred by 130 min. At the higher insulin levels (greater than or equal to 100 microU/ml), C-peptide levels fell rapidly, with an apparent t1/2 of 13 min, which approximates estimates for the t1/2 of circulating C-peptide in man. This is consistent with an immediate 70% inhibition of the basal rate of insulin secretion. At the lower insulin level (37 +/- 2 microU/ml), C-peptide levels fell to 30% of basal values less rapidly (apparent t1/2, 33 min), suggesting that 70% inhibition of basal insulin secretion rates was achieved more slowly. In NIDDM subjects, primed continuous insulin infusion rates of 15, 40, 120, and 1200 mU/M2 X min acutely raised serum insulin to steady state levels of 49 +/- 7, 93 +/- 11,364 +/- 31, and 10,003 +/- 988 microU/ml. During studies at basal hyperglycemia, only minimal C-peptide suppression was found, even at pharmacological insulin levels (10,003 +/- 988 microU/ml). However, if plasma glucose was allowed to fall during the insulin infusions, there was a rapid decrease in serum C-peptide to 30% of basal levels, analogous to that in normal subjects. Three weeks of intensive insulin therapy did not alter C-peptide suppression under conditions of hyperinsulinemia and falling plasma glucose. The following conclusions were reached. 1) In normal subjects, insulin (40-1000 microU/ml) inhibits its own secretion in a dose-responsive manner; more time is required to achieve maximal 70% suppression at the lower insulin level (40 microU/ml). 2) In NIDDM studied at basal hyperglycemia, insulin has minimal ability to suppress its own secretion. Thus, impaired feedback inhibition could contribute to basal hyperinsulinemia. 3) Under conditions of hyperinsulinemia and falling plasma glucose, insulin secretion is rapidly suppressed in NIDDM (analogous to that in normal subjects studied during euglycemia.     

Increased insulin secretion in response to glucose in isolated islets of Langerhans from bile duct-occluded rats

In a recent study, it was demonstrated that following i.v. injection of glucose, plasma insulin levels increased more in cholestatic rats than in control rats. This could theoretically be due to either a potentiated insulin secretion or an inhibited liver extraction of insulin in cholestatic rats. In the present study, we report the influence of obstructive jaundice on insulin secretion from isolated islets of Langerhans 3 weeks after bile duct occlusion or sham operation in rats. We found that insulin secretion from islets of control rats (250 +/- 29 microU/ml) and of bile duct-occluded rats (260 +/- 24 microU/ml) was not significantly different in a medium with a low glucose concentration (3.3 mM). In contrast, at a high glucose level (16.7 mM), an increased insulin secretion was seen from islets of cholestatic rats (469 +/- 14 microU/ml) as compared with control rats (370 +/- 19 microU/ml) (p less than 0.001). These results indicate that the increased plasma insulin levels found in vivo during cholestasis may not merely reflect a decreased liver clearance but be attributed to a potentiation of glucose-induced insulin secretion.     

Prolonged mild hyperglycemia induces vagally mediated compensatory increase in C-Peptide secretion in humans

Experimentally induced prolonged hyperglycemia increases insulin release in humans, and in animals has been demonstrated to increase vagal efferent activity. The objective of the present experiment was to determine whether in humans, the compensatory increase in insulin release in response to short-term mild hyperglycemia is mediated by an induction of vagal efferent activity. Lean male subjects (n = 11; body mass index, 23.6 +/- 0.8 kg/m(2)) underwent a frequently sampled iv glucose tolerance test (FSIGT) to determine B cell function and insulin sensitivity. Subjects were then tested under four conditions over 4 months. Subjects were infused for 48 h with either glucose (15% dextrose at 200 mg/m(2).min) or saline (50 ml/h). Three hours after termination of the infusion, an FSIGT was administered in the presence of either saline or atropine (0.4 mg/m(2) bolus: 0.4 mg/m(2).h). Glucose (117 +/- 14 vs. 98 +/- 5 mg/dl) and insulin (49.5 +/- 10 vs. 23 +/- 5 muU/ml) levels were significantly elevated during the 48-h glucose infusion compared with those during saline treatment. Forty-eight-hour glucose infusions increased insulin and C-peptide levels during the FSIGT. When the FSIGT was conducted in the presence of atropine after glucose infusion, C-peptide levels were significantly attenuated during the period of endogenous insulin secretion (0-20 min; 31.8 +/- 13 vs. 39.2 +/- 11.9, atropine vs. no atropine) and exogenous insulin administration [20-40 min; 18.8 +/- 10.8 vs. 31.6 +/- 12.9., atropine vs. no atropine; F(3,9) = 4.99; P < 0.026]. A significant negative correlation was found between the repression of C-peptide by muscarinic blockade and the magnitude of the C-peptide response to the glucose infusion (r = 0.60; P < 0.045). Insulin AUC was not significantly altered by the presence of muscarinic blockade. In summary, we found that prolonged mild hyperglycemia results in a compensatory increase in C-peptide secretion, which is partially mediated by an induction in vagal efferent activity.     

Insulin secretion, insulin sensitivity and glucose-mediated glucose disposal in thyrotoxicosis: a minimal model analysis

In order to evaluate simultaneously in thyrotoxic subjects the relative contributions of insulin secretion, insulin-sensitivity (SI) and glucose-mediated (SG) glucose disposal to overall glucose tolerance, seven non-obese patients with thyrotoxicosis were studied by the minimal model analysis of the frequently sampled intravenous glucose tolerance test, before and greater than 1 month after being rendered euthyroid, and compared with eight healthy control subjects. Basal glucose, C-peptide and glucagon levels were similar in all groups but, in the toxic and euthyroid states, basal insulin levels were significantly elevated compared to the control group (11.2 +/- 2.0 and 7.9 +/- 1.1 vs 5.1 +/- 0.6 microU/ml, mean +/- SE, P less than 0.02). FFA levels were raised in the thyrotoxic subjects prior to treatment (0.95 +/- 0.11 vs 0.68 +/- 0.08 and 0.54 +/- 0.08 mmol/l, P less than 0.02). Glucose tolerance (Kg) was reduced in the thyrotoxic subjects compared to the euthyroid state (1.16 +/- 0.12 vs 1.44 +/- 0.13 per min, P less than 0.025) and control group (1.44 +/- 1.0 per min, 0.05 less than P less than 0.1). First phase (phi 1) and second phase (phi 2) insulin release were both significantly elevated in the thyrotoxic and euthyroid states compared to the control group (phi 1 7.10 +/- 1.88 and 5.29 +/- 1.03 vs 1.72 +/- 0.17 microU/mg/min X 10(-2), P less than 0.01; phi 2 18.64 +/- 3.14 and 16.74 +/- 4.48 vs 9.23 +/- 0.74 microU/mg/min X 10(-2) respectively, P less than 0.02). SG was similar in all groups but SI was significantly reduced in the thyrotoxic subjects compared to the control group (2.24 +/- 0.62 vs 5.92 +/- 1.50/min/microU/ml X 10(4), P less than 0.02) and rose post-treatment in the euthyroid subjects (4.23 +/- 1.75/min/microU/ml X 10(4)). In the thyrotoxic subjects before and after treatment, log SI correlated negatively with basal FFA levels (r = -0.57, P less than 0.05) and with phi 2 (r = -0.58, P less than 0.05). The fractional clearance rate of insulin was unaltered by the thyrotoxic state. It is concluded that in thyrotoxicosis the impairment of Kg is due to reduced insulin sensitivity in the presence of enhanced insulin secretion, but glucose-mediated glucose disposal is unaltered by the toxic state.     

Direct assessment of splanchnic uptake and metabolic effects of human and porcine insulin

The hepatic vein catheterization technique was used to quantitate the splanchnic uptake and the metabolic effects of biosynthetic human insulin (BHI) and porcine insulin (PI) in normal man. BHI and PI were infused into a peripheral vein (0.9-1.3 mU kg-1 min-1) for 60 min together with SRIH (0.6 mg/h) to inhibit endogenous insulin secretion and glucose to induce moderate hyperglycemia (9-10 mmol/liter). During the infusion period, arterial-hepatic venous difference of plasma C-peptide as well as splanchnic C-peptide output fell by more than 98% indicating virtually complete cessation of endogenous insulin release. Under these conditions, the arterial-hepatic venous differences in plasma insulin concentrations represent a valid and direct measurement of splanchnic insulin uptake. During BHI infusion, arterial insulin levels rose to 82 +/- 11 (SE) microU/ml (range: 33-105 microU/ml). Splanchnic insulin uptake paralleled the rise of arterial insulin, reaching 430 +/- 72 microU kg-1 min-1 at 60 min. No appreciable difference between BHI and PI was demonstrable. A highly significant correlation between arterial insulin concentrations and splanchnic insulin uptake was found (r = 0.816; P less than 0.001). Accordingly, both fractional splanchnic insulin extraction and splanchnic insulin clearance remained unchanged throughout insulin infusion and averaged 70 +/- 4% and 5.3 +/- 2 ml kg-1 min-1, respectively. With BHI infusion, splanchnic glucose balance (-8.5 +/- 0.9 mumol kg-1 min-1, basal) became positive (7.3 +/- 1 mumol kg-1 min-1). In contrast, basal splanchnic lactate uptake was inhibited by BHI and there was lactate production (from 3.4 +/- 0.9 to -1.7 +/- 1.4 mumol kg-1 min-1). Similar changes in splanchnic glucose and lactate metabolism occurred during PI infusion. These studies indicate that: 1) A considerable amount of insulin (70 +/- 4%) is extracted by the splanchnic bed on a single passage, after exogenous administration of either human insulin or PI; 2) over a physiological range of insulin concentrations (33-105 microU/ml) a linear relationship exists between arterial insulin concentrations and splanchnic insulin removal; and 3) BHI and PI do not differ appreciably with respect to their uptake and metabolic effects at the splanchnic level.     

Hepatic and peripheral insulin resistance following streptozotocin-induced insulin deficiency in the dog

Insulin resistance and insulin deficiency are both present in many patients with diabetes mellitus. We tested the hypothesis that insulin resistance can evolve from a primary lesion of the beta-cell secretory function. Insulin-mediated glucose uptake (insulin clamp), endogenous glucose production, and glucose-stimulated insulin secretion (hyperglycemic clamp) were measured in awake dogs before and four to six weeks after streptozotocin-induced diabetes mellitus. Streptozotocin (30 mg/kg) resulted in a significant rise in the mean fasting plasma glucose concentration from 104 +/- 2 mg/100 mL to 200 +/- 34 mg/100 mL, (P less than 0.05), and a slight decrease in the mean fasting plasma insulin concentration (from 21 +/- 2 microU/mL to 15 +/- 2 microU/mL). Under conditions of steady-state hyperglycemia (+75 mg/100 mL hyperglycemic clamp, insulin secretion was reduced by 75% in the streptozotocin-treated dogs (P less than 0.025), and the total amount of glucose metabolized decreased from 13.56 +/- 1.04 to 4.74 +/- 0.70 mg/min X kg (P less than 0.001). In the postabsorptive state, endogenous glucose production was slightly, although not significantly, higher in the diabetic dogs (3.05 +/- 0.46 v 2.51 +/- 0.22 mg/min . kg), while the glucose clearance rate was 35% lower (P less than 0.001). When the plasma insulin concentration was increased to approximately 45 microU/mL (insulin clamp) while holding plasma glucose constant at the respective fasting levels (99 +/- 1 and 186 +/- 30 mg/100 mL), endogenous glucose production was completely suppressed in control dogs but suppressed by only 51% (1.46 +/- 0.37 mg/min . kg, P less than 0.025) in diabetic animals.(ABSTRACT TRUNCATED AT 250 WORDS)     

Insulin and glucagon secretion are suppressed equally during both hyper- and euglycemia by moderate hyperinsulinemia in patients with diabetes mellitus

Hyper- and euglycemic clamp studies were performed in patients with noninsulin-dependent diabetes mellitus to examine the effects of exogenous insulin administration on insulin and glucagon secretion. Plasma glucose was kept at the fasting level [mean, 10.0 +/- 0.2 (+/- SE) mmol/L; hyperglycemic clamp], and graded doses of insulin (1, 3, and 10 mU/kg.min, each for 50 min) were infused. The plasma C-peptide level gradually decreased from 523 +/- 66 to 291 +/- 43 pmol/L (n = 13; P less than 0.005) by the end of the hyperglycemic clamp study. After 90 min of equilibration with euglycemia (5.4 +/- 0.1 mmol/L; euglycemic clamp), the same insulin infusion protocol caused a similar decrease in the plasma C-peptide level. With the same glucose clamp protocol, physiological hyperinsulinemia for 150 min (676 +/- 40 pmol/L), obtained by the infusion of 2 mU/kg.min insulin, caused suppression of the plasma C-peptide level from 536 +/- 119 to 273 +/- 65 pmol/L during hyperglycemia and from 268 +/- 41 to 151 +/- 23 pmol/L during euglycemia (n = 9; P less than 0.005 in each clamp). Plasma glucagon was suppressed to a similar degree in both glycemic states. These results demonstrate that 1) insulin secretion in non-insulin-dependent diabetes mellitus is suppressed by high physiological doses of exogenous insulin in both the hyper- and euglycemic states, the degree of inhibition being independent of the plasma glucose level; and 2) glucagon secretion is also inhibited by such doses of exogenous insulin.