Importance of Growth Hormone for Blood Glucose Regulation Following Insulin-induced Nocturnal Hypoglycemia in Insulin-dependent Diabetes Mellitus

ABSTRACT The effect of growth hormone (GH) on the glucose homeostasis following nocturnal hypoglycemia was studied between 4 a.m. and noon in eight male patients with insulin-dependent diabetes mellitus (IDDM) by a somatostatin (250 μg/h)-insulin (0.4 mU/kg/min)-glucose (6 mg/kg/min)-infusion test (SIGIT). The patients participated in two experiments in which hypoglycemia at 4 a.m. was induced by i.v. insulin (1.5 mU/kg/min). In both experiments the endogenous secretion of GH was suppressed by somatostatin (250 μg/h) and glucagon (0.5 ng/kg/min) was given as substitute for the somatostatin-induced suppression of endogenous glucagon secretion. GH (20 mU/kg/h) or saline was given for 60 min from nadir blood glucose in random order. Mean nadir glucose values were the same in both studies (1.7 ± 0.2 vs. 1.7 ± 0.1 mmol/l) and no differences were registered in plasma-free insulin, glucagon and the responses of adrenaline and Cortisol to hypoglycemia. The infusion of GH resulted in plasma GH levels of about 50 μg/l at the end of the infusion, thereafter decreasing to low or immeasurable levels within 2 hours. Infusion of GH evoked a marked hyperglycemia within 4 hours. It is concluded that when hypoglycemia is accompanied by a transient increase in plasma GH, insulin resistance occurs after a lag period of approximately 4 hours and that this effect persists for at least another 4 hours.     

Characterization of the late posthypoglycemic insulin resistance in insulin-dependent diabetes mellitus

The insulin effect (6.5 to 7.5 hours) following hypoglycemia was studied with the euglycemic clamp technique in eight patients with insulin-dependent diabeteses mellitus (IDDM). The results were compared with a control study with the same insulin infusion, but where hypoglycemia was prevented by a glucose infusion. Glucose production (Ra) and utilization (Rd) were evaluated with D-(3-3H) glucose infusion. Hypoglycemia (glucose nadir, 1.5 +/- 0.1 mmol/L) caused a marked increase in cortisol and growth hormone, whereas the release of adrenaline and, in particular, glucagon was low. The plasma free insulin levels were similar in the studies, including during the clamp periods. The glucose infusion rates (GIR) were significantly lower after the hypoglycemia as compared with the control study (control, 2.4 +/- 0.3; hypoglycemia, 1.5 +/- 0.3 mg/kg x min; P less than .05). Thus, hypoglycemia induces prolonged insulin resistance. The posthypoglycemic insulin resistance during a moderate hyperinsulinemic (approximately 30 mU/L) clamp was mainly due to a decreased insulin effect on glucose utilization (control, 2.9 +/- 0.2; hypoglycemia, 2.2 +/- 0.2 mg/kg x min; P less than .02), whereas the insulin effect on glucose production was not significantly different after hypoglycemia.     

Glucagon and hepatic glucose production: modulation by low-dose bradykinin infusion

The effect of a low-dose bradykinin (BK) infusion (30 ng/kg min) on glucagon-induced hepatic glucose production and glucose cycling was studied in five normal volunteers. Studies were performed during constant insulin concentration as achieved by simultaneous somatostatin infusion and insulin replacement. In the basal period glucagon was infused at a rate of 0.5 ng/kg min. Then, glucagon infusion rate was increased to 3 ng/kg min to test the response to hyperglucagonemia. In a second set of experiments BK was infused concomitantly with the high dose glucagon. Each subject served as his own control. BK infusion did not prevent the glucagon-induced rise in hepatic glucose production and glucose cycling. However, at a later stage BK accelerated the negative feedback mechanisms activated by glucagon (decrease in hepatic glucose production) significantly. These findings suggest that intravenous BK may interact with mechanisms involved in the down-regulation of hepatic glucagon effects.     

Autoregulation of endogenous glucose production during hyperglucagonemia

Increased endogenous glucose production (EGP) contributes to fasting hyperglycemia in type II diabetes. In nondiabetic subjects, increased gluconeogenesis from lactate does not increase EGP. Type 2 diabetes is associated with hyperglucagonemia. The present study was undertaken to examine whether physiologic elevation of plasma glucagon overrides autoregulation of EGP. Eight healthy volunteers were studied on 2 occasions, once during a 3-hour infusion of 30 micromol/kg/min Na-lactate and once during a control infusion of Na-bicarbonate. Plasma glucagon, insulin, and growth hormone were clamped at identical levels in both experiments. Rates of appearance of glucose, lactate, and gluconeogenesis from lactate were measured by tracer techniques. Glucagon infusion rate was elevated when the lactate or bicarbonate infusions were started to induce physiologic hyperglucagonemia. Plasma glucagon increased from baseline levels (234 +/- 21 ng/L and 211 +/- 23 ng/L) to 313 +/- 47 ng/L (bicarbonate experiments) and 329 +/- 43 ng/L (lactate experiments, means +/- SE, P >.3). Lactate infusion increased plasma lactate concentrations from 1.1 +/- 0.9 to 4.6 +/- 0.5 mmol/L (P =.0003). Lactate conversion to glucose increased from 1.5+/-0.3 to 2.8+/-0.8 micromol/kg/min (P =.03) and from 1.7 +/- 0.3 to 8.1 +/- 0.8 micromol/kg/min (P =.0003) in the bicarbonate and lactate experiments, respectively. The increments in lactate conversion to glucose differed significantly (P =.0008). Nevertheless, plasma glucose and EGP were not different in the bicarbonate and lactate experiments: 5.4 +/- 0.5 versus 6.6 +/- 0.7 mmol/L (P =.21), and 10.5 +/- 0.6 versus 11.6 +/- 0.6 micromol/kg/min (P =.19). We conclude that in normal volunteers, neither hyperglucagonemia nor the combination of hyperglucagonemia and increased substrate availability alters the autoregulation of EGP.     

INFLUENCE OF SOMATOSTATIN ON PLASMA CYCLIC AMP AND METABOLIC SUBSTRATE RESPONSES TO I.V. ADRENALINE AND GLUCAGON IN HUMANS

The influence of somatostatin (a bolus injection of 250 micrograms i.v. followed by 6 micrograms/min for 40 min) on the plasma cyclic AMP, insulin, glucose and non-esterified fatty acid (NEFA) responses to i.v. adrenaline (0.07 micrograms/kg body-weight/min for 20 min) and the plasma cyclic AMP, insulin and glucose responses to a bolus injection of i.v. glucagon (0.01 mg/kg BW) were studied in normal subjects. Somatostatin suppressed the insulin response to glucagon and inhibited the insulin rebound observed on termination of adrenaline infusion. The plasma glucose response to glucagon was exaggerated by somatostatin, reflecting insulin deficiency. Neither the plasma glucose or plasma non-esterified fatty acid responses to adrenaline were influenced by somatostatin. Adrenaline produced a three-fold and glucagon a twenty-fold rise in plasma cyclic AMP and 15 min. This was not influenced by concurrent somatostatin infusion, indicating that somatostatin is not a universal inhibitor of hormone stimulated adenylate cyclase activity. This is supported by the failure of somatostatin to inhibit the metabolic actions of glucagon and adrenaline thought to be mediated by cyclic AMP.     

Persistent effect of sustained hyperglucagonemia on glucose production in man.

In man prolonged infusions of glucagon cause a transient increase in glucose production. To determine whether this represents complete loss of effect of hyperglucagonemia on the liver or merely decreased hepatic responsiveness, glucagon (3 ng/kg/min) was infused in six normal subjects to produce sustained hyperglucagonemia for 180 min; at this time glucagon infusions were stopped for 60 min, then restarted at the same rate for 60 min and finally increased to 7.5 ng/kg/min for 30 min. Glucose production (Ra) and utilization (Rd) were measured isotopically. Initially glucagon infusion increased Ra transiently from 1.8 +/- 0.1 mg/kg/min to a maximum at 15 min of 2.5 +/- 0.2 mg/kg/min (p less than .01); Ra returned to basal values by 60 min and remained there until the glucagon infusion was stopped, whereupon it abruptly declined to a nadir of 1.4 +/- 0.1 mg/kg/min, a value significantly below baseline levels, p less than .005. Upon restarting the glucagon infusion, Ra increased to a similar extent as observed with the initial infusion and then returned to basal levels; when the glucagon infusion rate was increased to 7.5 ng/kg/min, Ra again increased. These results indicate that sustained hyperglucagonemia, despite apparent waning of its effect, continues to modulate hepatic glucose production.     

Physiological levels of glucagon do not influence lipolysis in abdominal adipose tissue as assessed by microdialysis

To determine whether glucagon stimulates lipolysis in adipose tissue, seven healthy young male volunteers were studied, with indwelling microdialysis catheters placed sc in abdominal adipose tissue. Subjects were studied three times: 1) during euglucagonemia (EG; glucagon infusion rate, 0.5 ng/kg.min); 2) during hyperglucagonemia (HG; (glucagon infusion rate, 1.5 ng/kg.min); and 3) during EG and a concomitant glucose infusion mimicking the glucose profile from the day of HG (EG+G). Somatostatin (450 microg/h) was infused to suppress hormonal secretion, and replacement doses of insulin and GH were administered. Sampling was done every 30 min for 420 min. Baseline circulating values of insulin, C-peptide, glucagon, GH, glycerol, and free fatty acids were comparable in all three conditions. During EG and EG+G, plasma glucagon was maintained at fasting level (20-40 ng/L); whereas, during HG, it increased (110-130 ng/L). Interstitial concentrations of glycerol were similar in the three conditions [30,870 +/- 5,946 (EG) vs. 31,074 +/- 7,092 (HG) vs. 29,451 +/- 6,217 (EG+G) micromol/L.120 min, P = 0.98]. Plasma glycerol (ANOVA, P = 0.5) and free fatty acids (ANOVA, P = 0.3) were comparable during the different glucagon challenges. We conclude that HG per se does not increase interstitial glycerol (and thus lipolysis) in abdominal sc adipose tissue; nor does modest hyperglycemia, during basal insulinemia and glucagonemia, influence indices of abdominal sc lipolysis.     

Impaired Counter Regulation of Hypoglycemia in a Group of Insulin-dependent Diabetics with Recurrent Episodes of Severe Hypoglycemia

Abstract The counterregulatory response to insulin-induced hypoglycemia was investigated in 22 insulin-dependent diabetics (IDD) with recurrent hypoglycemia and in 6 healthy volunteers. Hypoglycemia was induced by a constant rate infusion of insulin (2.4 U/h) up to four hours. Conventional insulin therapy was changed to an i.v. infusion of regular insulin 24 hours prior to the experiment. The presence of diabetic autonomic neuropathy was evaluated by respiratory sinus arrhythmia and Valsalva maneuver. In healthy subjects, blood glucose was decreased to 2.5 mmol, here reaching steady state level and giving rise to marked glucagon and growth hormone (GH) responses. The majority of IDD (group A) reached a slightly lower steady state glucose level and exhibited similar glucagon and GH responses while the epinephrine response was augmented. Six IDD (group B) showed a continuous decrease in blood glucose to 1.2+0.1 mmol/l at which level the infusion of insulin was discontinued due to neuroglucopenic symptoms. These subjects had no glucagon and epinephrine responses while their GH and cortisol responses were normal. A comparison of the diabetic groups revealed a longer duration of diabetes and a more impaired autonomic nervous function in group B while glycosylated hemoglobin was similar. It is concluded that most IDD have normal hormonal responses (epinephrine, glucagon, GH, cortisol) and normal counterregulartory capacity to hypoglycemia induced by a prolonged infusion of a moderate dose of insulin. Some patients with long-term diabetes and impaired capacity to counteract hypoglycemia exhibit deficient glucagon and epinephrine responses to hypoglycemia.     

Effects of glucagon-like peptide 1 on counterregulatory hormone responses, cognitive functions, and insulin secretion during hyperinsulinemic, stepped hypoglycemic clamp experiments in healthy volunteers

Glucagon-like peptide 1 (GLP-1) and analogues are being evaluated as a new therapeutic principle for the treatment of type 2 diabetes. GLP-1 suppresses glucagon secretion, which could lead to disturbances of hypoglycemia counterregulation. This has, however, not been tested. Nine healthy volunteers with normal oral glucose tolerance received infusions of regular insulin (1 mU x kg(-1) x min(-1)) over 360 min on two occasions in the fasting state. Capillary glucose concentrations were clamped at plateaus of 4.3, 3.7, 3.0, and 2.3 mmol/liter for 90 min each (stepwise hypoglycemic clamp); on one occasion, GLP-1 (1.2 pmol x kg(-1) x min(-1)) was administered i.v. (steady-state concentration, approximately 125 pmol/liter); on the other occasion, NaCl was administered as placebo. Glucagon, cortisol, GH (immunoassays), and catecholamines (radioenzymatic assay) were determined, autonomous and neuroglucopenic symptoms were assessed, and cognitive function was tested at each plateau. Insulin secretion rates were estimated by deconvolution (two-compartment model of C-peptide kinetics). At insulin concentrations of approximately 45 mU/liter, glucose infusion rates were similar with and without GLP-1 (P = 0.26). Only during the euglycemic plateau (4.3 mmol/liter), GLP-1 suppressed glucagon concentrations (4.1 +/- 0.4 vs. 6.5 +/- 0.7 pmol/liter; P = 0.012); at all hypoglycemic plateaus, glucagon increased similarly with GLP-1 or placebo, to maximum values greater than 20 pmol/liter (P = 0.97). The other counterregulatory hormones and autonomic or neuroglucopenic symptom scores increased, and cognitive functions decreased with decreasing glucose concentrations, but there were no significant differences comparing experiments with GLP-1 or placebo, except for a significant reduction of GH responses during hypoglycemia with GLP-1 (P = 0.04). GLP-1 stimulated insulin secretion only at plasma glucose concentrations of at least 4.3 mmol/liter. In conclusion, the suppression of glucagon by GLP-1 does occur at euglycemia, but not at hypoglycemic plasma glucose concentrations (< or = 3.7 mmol/liter). GLP-1 does not impair overall hypoglycemia counterregulation except for a reduction in GH responses, which is in line with other findings demonstrating pituitary actions of GLP-1. Below plasma glucose concentrations of 4.3 mmol/liter, the insulinotropic action of GLP-1 is negligible.     

Counterregulatory adaptation to recurrent hypoglycemia in normal humans

We evaluated the effect of antecedent hypoglycemia on glucose counterregulation during hypoglycemia in non-diabetic human subjects. In single hypoglycemia studies, glucose production [( 3H]3-glucose) and counterregulatory hormone concentrations were measured (after a 3.5-h baseline period of euglycemia) during 120 min of hypoglycemia (glucose clamped at 3.0 mmol/L). During the final 60 min of hypoglycemia, counterregulation resulted in significant increments in glucose production (12.88 +/- 0.83 mumol/kg.min), and plasma glucagon (IRG; 185 +/- 22 ng/L), GH (29.3 +/- 7.0 micrograms/L), cortisol (630 +/- 100 nmol/L), epinephrine (3.44 +/- 0.76 nmol/L), and norepinephrine (2.02 +/- 0.21 nmol/L). In the recurrent hypoglycemia experiment, an antecedent period of identical hypoglycemia was induced. Glucose counterregulation during the second of two periods of hypoglycemia (HYPO 2) was then compared to that in single hypoglycemia studies. During HYPO 2, there were decreased responses in Ra (by 32%; P less than 0.03), GH (by 67%; P less than 0.05), F (by 41%; P less than 0.03), and norepinephrine (by 20%; P = 0.03) compared to those in the single hypoglycemia study. In contrast, plasma IRG values were similar in the single hypoglycemia studies and HYPO 2, but were reduced relative to those during the first hypoglycemic period of recurrent hypoglycemia (IRG, 263 +/- 18 ng/L; P less than 0.025 vs. HYPO 2 and P less than 0.05 vs. single hypoglycemia). Our results suggest that 1) antecedent hypoglycemia may alter glucose counterregulation during hypoglycemia; and 2) recurrent hypoglycemia may result in alterations in reduction of hepatic glucose production.     

A high concentration of circulating insulin suppresses the glucagon response to hypoglycemia in normal man.

In an attempt to clarify whether circulating insulin per se exerts an inhibitory effect on the hormonal responses to hypoglycemia, with special emphasis on glucagon secretion, nine healthy volunteers were exposed to low dose (244 pmol/kg.h) and high dose (1034 pmol/kg.h) iv insulin infusions for 3 h on two separate occasions. A close to identical arterial hypoglycemia of about 3.4 mmo/L was obtained in both tests by glucose clamping during the high dose test. The corresponding glucose concentration in the venous blood was significantly lower in the high dose test (2.5 +/- 0.1 vs. 3.0 +/- 0.1 mmol/L; P less than 0.01), while the plasma free insulin level was 4 times higher in the high dose test (897 +/- 50 vs. 208 +/- 14 pmol/L). Plasma glucagon was elevated in both experiments, but its rise was reduced during the high dose test after 1 h, yielding an incremental area under the glucagon curve that was significantly smaller than that obtained during the low dose test (213 +/- 70 vs. 348 +/- 81 ng/L.h; P less than 0.05). The plasma adrenaline, noradrenaline, GH, C-peptide, pancreatic polypeptide, and somatostatin profiles were similar in the two tests. We conclude that an inhibitory effect of circulating insulin on the glucagon response to hypoglycemia can be demonstrated in normal man during an infusion of insulin yielding a plasma concentration of about 900 pmol/L. The responses of other hormones studied are not significantly influenced by the circulating insulin level.     

Idiopathic reactive hypoglycemia: a role for glucagon?

We previously reported that patients with idiopathic reactive hypoglycemia (plasma glucose concentration lower than 2.5 mmol/L 2-4 h after the ingestion of 75 g of glucose) display reduced or absent counterregulatory response of the glucagon secretion and increased insulin sensitivity. In order to examine the effect of glucagon on the increased insulin sensitivity in these patients, 12 subjects with idiopathic reactive hypoglycemia underwent a two-step hyperinsulinemic (1 mU/kg.min) euglycemic glucose clamp and were compared with 12 normal control subjects matched for age, weight and sex. During the first step of the glucose clamp (only insulin + glucose infusion) the patients with Idiopathic Reactive Hypoglycemia required higher glucose infusion rates to maintain euglycemia than normal subjects (9.09 +/- 0.29 mg/kg. min vs 7.61 mg/kg.min). When basal glucagon secretion was replaced (+ somatostatin and glucagon, second step of the clamp) the glucose infusion rates required to maintain euglycemia in patients with Idiopathic Reactive Hypoglycemia significantly decreased (to 7.17 +/- 0.40 mg/kg.min) and resulted similar to normal subjects (7.64 +/- 0.41 mg/kg.min). Thus, in patients affected by Idiopathic Reactive Hypoglycemia, glucagon secretion may play an important role in the pathogenesis of the increased insulin sensitivity and hypoglycemia.     

Glucose turnover in insulinoma--a case report

To define glucose flux in a state of chronic endogenous insulin excess, a patient with an insulinoma was studied. Plasma glucose, insulin (IRI), glucagon (IRG) and glucose turnover ([3-3H]glucose infusion) were measured before and after insulinoma resection in the postabsorptive state (PA), during a glucose infusion adjusted to attain euglycemia (before insulinoma resection only) and following an intravenous glucagon bolus (1 mg). Before insulinoma resection, plasma glucose was 55 mg/dl, glucose production (Ra) and disappearance (Rd) were equal (1.6 mg/kg/min) and glucose clearance was elevated (2.8 ml/kg/min) in PA. When glycemia was raised with a glucose infusion to 77 mg/dl, Rd did not change; in contrast Ra dropped to zero. Plasma IRI and IRG concentrations were 0.7 ng/ml and 110 pg/ml respectively before glucose infusion and remained constant throughout. After resection of the insulinoma, glycemia in PA was 103 mg/dl, Ra and Rd were increased slightly to 1.9 mg/kg/min while the metabolic clearance of glucose was decreased by 25% (2.1 ml/kg/min). Glucagon stimulation pre- and postinsulinoma resection resulted in significant increases in glycemia and IRI. We conclude that hypoglycemia with insulinoma is a consequence of decreased glucose production and increased glucose clearance. Hepatic sensitivity to small increments in glycemia is markedly enhanced so as to fully suppress endogenous glucose production at euglycemic levels in the absence of any change in IRI and IRG. The mechanisms controlling hepatic Ra in insulinoma appear different from normal.     

Counterregulatory response to hypoglycemia differs according to the insulin delivery route, but does not affect glucose production in normal humans

The magnitude of the counterregulatory response to insulin-induced hypoglycemia is primarily determined by the degree of hypoglycemia. We examined whether the route of acute insulin delivery (portal or peripheral venous) is also important in determining the magnitude of the counterregulatory response to hypoglycemia in nine healthy nondiabetic men. Pancreatic insulin secretion, stimulated by an i.v. tolbutamide infusion (portal insulin study), was matched with an exogenous insulin infusion into the peripheral vein 4-6 weeks later (peripheral insulin study). Each study consisted of a 150-min baseline tracer equilibration period, a 180-min euglycemic hyperinsulinemic (portal or peripheral insulin delivery) period, a 60-min hypoglycemic period in which insulin secretion diminished during tolbutamide or was reduced during exogenous insulin, and a 30-min recovery period. Peripheral venous glucose concentrations were well matched in the portal and peripheral studies during euglycemia and hypoglycemia (glucose nadir, 2.9 +/- 0.1 mmol/L in the portal and 2.7 +/- 0.1 mmol/L in the peripheral; mean +/- SEM; P = NS), and insulin concentrations were about 1.5-fold higher throughout the experiment in the peripheral vs. the portal insulin study due to the first pass extraction of insulin in the portal study. There was a much greater increment (P < 0.0001) in FFA in the portal vs. the peripheral study (area under the curve: portal, 19.5 +/- 3.9 mmol/L x 90 min; peripheral, 3.3 +/- 1.1 mmol/L x 90 min), whereas plasma glucagon and GH were higher in the peripheral study (P = 0.01 for glucagon; P = 0.015 for GH). There was no significant difference between studies in epinephrine and norepinephrine responses to hypoglycemia or stimulation of endogenous glucose production (area under the curve: portal, 636 +/- 103 micromol/kg x 90 min; peripheral, 705 +/- 69 micromol/kg x 90 min; P = NS). In summary, we have shown that the glucagon, GH, and FFA responses to hypoglycemia during insulin dissipation are affected by the route of insulin delivery and are not controlled exclusively by the nadir blood glucose level. The clinical importance of these observations in diabetic subjects as they relate to route of insulin delivery (portal or peripheral) during insulin dissipation remains to be determined.     

Protective effect of insulin against hypoglycemia-associated counterregulatory failure.

Antecedent hypoglycemic episodes reduce the counterregulatory neuroendocrine response to hypoglycemia. The role of insulin in the mechanism responsible for the antecedent hypoglycemia causing subsequent counterregulatory failure has not been elucidated. We performed antecedent hypoglycemic clamps (56 mg/dL) lasting 2 h with differing degrees of hyperinsulinemia, which were followed by 6-h stepwise hypoglycemic clamps (76-66-56-46 mg/dL) on the next day. Experiments were carried out in 30 young, healthy men. Fifteen of these subjects were tested on 2 occasions. On 1 occasion the antecedent hypoglycemia was induced by insulin infusion at a rate of 1.5 mU/min x kg (low insulin-ante-hypo); on the other occasion the insulin infusion rate was 15.0 mU/min x kg (high insulin-ante-hypo). Both sessions were separated by at least 4 weeks, and their order was balanced across subjects. The remaining 15 subjects (control group) received the same stepwise hypoglycemic clamp as the other subjects, but without antecedent hypoglycemia. During the stepwise hypoglycemic clamp, the counterregulatory increases in ACTH, cortisol, and norepinephrine were significantly blunted after the low insulin-ante-hypo (P < 0.01, P < 0.05, and P < 0.05, respectively) but not after the high insulin-ante-hypo (P = 0.12, P = 0.92, and P = 0.19, respectively) compared to that in the control group. The cortisol, norepinephrine, and glucagon responses were greater after the high than after the low insulin-ante-hypo (all P < 0.05). In conclusion, the present study clearly demonstrates that even a single episode of mild hypoglycemia reduces neuroendocrine counterregulation 18-24 h later. Insulin has a moderate protective effect on subsequent counterregulation.     

Increased responsiveness to the hyperglycemic, hyperglucagonemic and hyperinsulinemic effects of circulating norepinephrine in ob/ob mice

OBJECTIVE: Several studies have implicated increased sympathetic tone as a contributing factor to the hyperglycemia and hyperglucagonemia of ob/ob mice. However, the responsiveness of plasma glucose, insulin and glucagon to circulating norepinephrine (NE) in ob/ob vs normal lean mice has never been described. Therefore, the present study investigated the effect of a 15 min intravenous NE infusion (1 pmol/min/g) on plasma glucose, insulin and glucagon in anesthetized lean, ob/ob, ob/ob-concurrent yohimbine (alpha(2) antagonist) treated, and ob/ob-chronically sympatholytic dopamine agonist treated (for 14 days prior to infusion) mice. In an effort to gain insight into a possible relation between norepinephrine, hyperglucagonemia and hyperinsulinemia in ob/ob mice, this study also examined the isolated islet responses to NE and glucagon in lean, ob/ob and ob/ob-sympatholytic dopamine agonist treated mice. RESULTS: Basal humoral values of glucose, insulin and glucagon were all elevated in ob/ob vs lean mice (by 63, 1900 and 63%, respectively, P<0.01). However, NE infusion further increased levels of glucose, insulin and glucagon in ob/ob (by 80, 90 and 60%, respectively, P<0.05) but not in lean mice (between group difference for all parameters P<0.05). Acute concurrent yohimbine treatment as well as chronic prior sympatholytic dopamine agonist treatment (bromocriptine plus SKF38393) simultaneously strongly aborgated or abolished all these humoral hypersensitivity responses to intravenous NE in ob/ob mice (P<0.05). Clamping the plasma glucose level in untreated ob/ob mice at a high level (30 mM) established by NE infusion did not significantly alter the plasma insulin level, suggesting that some other influence of NE was responsible for this insulin effect. Direct NE administration at 1 microM to islets from lean and ob/ob mice inhibited 15 mM glucose-stimulated insulin secretion in both groups, but at 0.1 microM it was inhibitory only in islets from ob/ob mice. However, glucagon (10 nM) increased 15 mM glucose-stimulated insulin secretion in ob/ob (by 170%, P<0.05) but not lean mice (between group difference P<0.05). CONCLUSION: These findings suggest that hypersensitivity to circulating NE may potentiate hyperglycemia and hyperglucagonemia in ob/ob mice, and the subsequent hyperglucagonemia coupled with increased islet beta-cell insulin secretory responsiveness to glucagon in ob/ob mice may support hyperinsulinemia, thus explaining the increased plasma insulin level response to intravenous NE in these animals. These findings further support a role for increased peripheral noradrenergic activities in the development and maintenance of the hyperglycemic, hyperglucagonemic and hyperinsulinemic state, characteristic of type 2 diabetes.     

Somatostatin enhances insulin-mediated glucose disposal in elderly subjects

Somatostatin (SRIH) infusion has been widely used in metabolic studies of carbohydrate metabolism. While the effects of SRIH itself on various aspects of carbohydrate economy have been assessed in young adults, such studies have not been conducted in the elderly, which represent an increasingly important study group. To examine the effect of SRIH on insulin-mediated glucose disposal in the elderly, we studied 12 (7 men and 5 women) healthy nonobese subjects, aged 65-80 yr. Paired 3-h euglycemic insulin clamp studies were performed in random order employing insulin alone (22 mU/m2.min) or insulin with SRIH (250 micrograms/h) and glucagon (0.4 ng/kg.min) to maintain normal basal plasma glucagon levels. Basal plasma insulin, glucose, glucagon, GH, and glucose production and disappearance were similar on each occasion. Steady state (10-180 min) mean plasma insulin [insulin alone, 298 +/- 12 (+/- SE); insulin; glucagon, and SRIH, 304 +/- 15 pmol/L] and glucagon (insulin alone, 85 +/- 7; insulin, glucagon, and SRIH, 96 +/- 9 ng/L) concentrations were similar. At steady state (150-180 min) glucose production was suppressed to similar levels (insulin alone, 26 +/- 7; insulin, glucagon, and SRIH, 36 +/- 13 mumol/kg.min). However, steady state glucose disposal was significantly higher during the SRIH infusion (insulin alone, 295 +/- 26; insulin, glucagon, and SRIH, 346 +/- 32 mumol/kg.min; P less than 0.02). We conclude that SRIH augments insulin-mediated glucose disposal in healthy older subjects at physiological levels of insulin.     

Insulin-antagonistic effects of pulsatile and continuous glucagon infusions in man--a comparison with the effect of adrenaline.

The insulin-antagonistic effects of pulsatile (3 min pulses every 20 min) and continuous glucagon infusions were studied over 4 h with the euglycemic clamp technique in healthy subjects. Comparisons were made to the effect of a continuous adrenaline infusion. Glucose production and utilization were evaluated with D-3-3H-glucose and somatostatin was used in all studies to inhibit the endogenous release of insulin and glucagon. The amount of glucagon given during the pulsatile infusions (27% of that during continuous infusion) was adjusted so that the peak glucagon levels were the same as during the continuous infusion (372 +/- 22 and 365 +/- 20 ng/L, respectively). The insulin-antagonistic effects of pulsatile and continuous glucagon infusions were similar during the first hour and imparied the insulin effect with 44 +/- 8 and 47 +/- 6%, respectively. However, when infused continuously, the effect of glucagon declined rapidly, whereas the effect of a pulsatile infusion decreased more slowly and was evident for 3 h. Raising the glucagon level 4-fold restored the insulin-antagonistic effect again suggesting that the cells had become desensitized. In contrast, the insulin-antagonistic effect of adrenaline was persistent throughout the 4 h of the study and impaired insulin action with 54 +/- 2%. The effects of pulsatile and continuous glucagon infusions were entirely due to the stimulation of glucose production while that of adrenaline mainly was due to inhibition of peripheral glucose uptake. In conclusion, the acute stimulatory effect of glucagon on glucose production is transient but it is better maintained when given as intermittent pulses rather than as a continuous infusion. In contrast, the insulin-antagonistic effect of adrenaline on glucose uptake is persistent for at least 4 h.     

Somatostatin does not alter insulin-mediated glucose disposal

We examined the effect of somatostatin (SRIH) infusion on insulin-mediated glucose disposal (Rd) in normal young subjects (n = 8) to determine the influence of SRIH on insulin action. Paired 3-h euglycemic insulin clamp studies were performed in random order employing insulin alone (25 mU/m2 X min) or insulin with SRIH (250 micrograms/h) and replacement of basal glucagon (0.4 ng/kg X min). Basal plasma glucose, insulin, glucagon (IRG), and GH concentrations, hepatic glucose production, and Rd were similar on each occasion. Steady state (10-180 min) plasma insulin insulin alone, 283 +/- 10 (+/- SEM); insulin, IRG, and SRIH, 284 +/- 10 pmol/L) and glucagon levels (insulin alone, 84 +/- 7; insulin, IRG, and SRIH, 82 +/- 7 ng/L) were similar. Hepatic glucose production (insulin alone, 0.66 +/- 0.12; insulin, IRG, and SRIH, 0.78 +/- 0.48 mg/kg X min) and Rd (insulin alone, 8.16 +/- 0.62; insulin, IRG, and SRIH, 8.17 +/- 0.61 mg/kg X min) were not different at steady state. We conclude that SRIH infusion with glucagon replacement does not augment insulin-mediated glucose disposal in normal young subjects at physiological insulin levels.     

Suppression of counterregulatory hormone response to hypoglycemia by insulin per se

Although assessment of counterregulatory hormone responses to hypoglycemia relies upon insulin to lower the glucose level, it is not known if the exogenous insulin does used itself influences the magnitude of the hormone response. To assess this, 12 normal subjects randomly received 2 hypoglycemic clamp studies in which the only variable was the insulin dose (0.6 or 5.0 mU/kg-min). Despite 10-fold differences in circulating insulin (265 +/- 29 vs 2576 +/- 222 pmol/L respectively), the hypoglycemic stimulus did not vary. Glucose levels fell over one hour, and then were maintained for two hours at the same hypoglycemic plateau (approximately 3.1 mmol/L for each study) by a variable glucose infusion. Although basal counterregulatory hormone levels in low and high dose studies were indistinguishable, during hypoglycemia the response of epinephrine, growth hormone, and glucagon was significantly suppressed when the degree of hyperinsulinemia was increased. We conclude that raising the magnitude of hyperinsulinemia suppresses the magnitude of the counterregulatory hormone response to hypoglycemia in normal subjects. This modulating effect of insulin per se is yet another variable in the interpretation of hypoglycemic counterregulation.