Influence of physiologic hyperglucagonemia on basal and insulin-inhibited splanchnic glucose output in normal man

To evaluate the effects of physiologic hyperglucagonemia on splanchnic glucose output, glucagon was infused in a dose of 3 ng/kg per min to healthy subjects in the basal state and after splanchnic glucose output had been inhibited by an infusion of glucose (2 mg/kg per min). In the basal state, infusion of glucagon causing a 309 +/- 25 pg/ml rise in plasma concentration was accompanied by a rapid increase in splanchnic glucose output to values two to three times basal by 7-15 min. The rise in arterial blood glucose (0.5-1.5 mM) correlated directly with the increment in splanchnic glucose output. Despite continued glucagon infusion, and in the face of stable insulin levels, splanchnic glucose output declined after 22 min, returning to basal levels by 30-45 min. In the subjects initially receiving the glucose infusion, arterial insulin concentration rose by 5-12 muU/ml, while splanchnic glucose output fell by 85-100%. Infusion of glucagon causing an increment in plasma glucagon concentration of 272 +/- 30 pg/ml reversed the inhibition in splanchnic glucose production within 5 min. Splanchnic glucose output reached a peak increment 60% above basal levels at 10 min, and subsequently declined to levels 20-25% below basal at 30-45 min. These findings provide direct evidence that physiologic increments in plasma glucagon stimulate splanchnic glucose output in the basal state and reverse insulin-mediated inhibition of splanchnic glucose production in normal man. The transient nature of the stimulatory effect of glucagon on splanchnic glucose output suggests the rapid development of inhibition or reversal of glucagon action. This inhibition does not appear to depend on increased insulin secretio.     

Metabolic consequences of atenolol and propranolol in treatment of essential hypertension

A six-month study of triglyceride, cholesterol, free fatty acid (FFA), glucose, insulin, growth hormone, and glucagon concentrations was carried out in asymptomatic hypertensive normal-weight men randomly allocated to treatment with atenolol or propranolol. A highly significant increase in the basal plasma triglyceride concentration was observed in propranolol-treated patients after three and six months' treatment, with a smaller but significant increase in atenolol-treated subjects after six months' treatment. The changes in triglyceride concentration could not be ascribed to variations in plasma insulin, growth hormone, or glucagon concentrations. Basal FFA concentrations were reduced during the first three months of treatment in both groups but returned to pretreatment levels after six months. Plasma cholesterol concentrations were unchanged by either agent.     

Inhibition of intestinal glucagon-like immunoreactivity (GLI) secretion by somatostatin in man

This work was undertaken to investigate the effect of somatostatin on intestinal glucagon-like immunoreactivity (GLI) secretion in man. In normal subjects GLI release is slightly stimulated by oral glucose while this sugar evokes a much greater GLI response in gastrectomized patients. Therefore, our study was performed in a group of such patients (N = 6). As expected, in the control experiments glucose ingestion elicited a clear-cut elevation of GLI plasma levels as measured with two antisera, 78J and R-8 (maximal peaks: 340% and 150% above basal values, respectively). Somatostatin infusion did not modify fasting GLI concentrations but completely abolished GLI response to glucose. Termination of the infusion was followed by a rebound of circulating GLI. The well-known suppressor effect of somatostatin on glucagon and insulin secretion was also detected. Finally, during somatostatin infusion the initial elevation of blood sugar after oral glucose, in the absence of insulin response, appeared considerably delayed. Our data demonstrate that somatostatin behaves as a potent inhibitory agent of GLI secretion in man. A retarding effect of somatostatin on glucose absorption is also compatible with our results.     

Mechanism of action of phenethylbiguanide (phenformin) in man. III. interrelationship between ethanol and phenethylibiguanide (PBG) in normal and diabetic subjects

A standard 4-hr ethanol infusion (236 mg/min) after a 3-day fast with and without phenformin (25 mg q.i.d.), with blood drawn every hour for 8 hr, was performed on five normal subjects, eight obese nondiabetics, seven obese chemical diabetics, and four nonobese diabetics. Control infusion induced in all subjects a decline in blood sugar levels during and/or after the alcohol challenge, with a parallel decrease in basal plasma insulin. Hypoglycemia and the decrease in insulin secretion were associated with increased plasma free fatty acid concentration. Addition of phenethylbiguanide (PBG) to the preparatory 3-day fast resulted in a greater drop in the blood glucose levels of the normal control subjects, obese and nonobese diabetics; in the obese nondiabetics, however, significantly lower degree of blood glucose decrease than control was elicited. Furthermore, obese nondiabetics altered their blood glucose-insulin interaction with apparent increased responsivess of the B cells of PBG. The results suggest that effects of phenformin on blood glucose levels are more dependent on the metabolic state of the patient than on a property of the drug itself.     

Mechanism of glucose intolerance during fasting: differences between lean and obese subjects

Oral glucose tolerance tests were performed on 14 lean and 14 obese nondiabetic subjects before and after a 6-day fast. In addition, insulin tolerance tests were performed on 8 lean and 8 obese subjects before and after starvation. Both in lean and obese subjects glucose tolerance deteriorated during starvation, but much more so in the lean population. During fasting, insulin elevation after a glucose load was significantly delayed in lean subjects but not in the obese. Circulating levels of factors known to affect glucose tolerance, such as glucagon, growth hormone, free fatty acids, and ketone bodies were higher in fasting lean than in fasting obese individuals. In normals fasting resulted in a significant decrease of the blood glucose response to insulin injection, whereas in fasting obese subjects glucose response was unchanged. The results obtained suggest that the effect of fasting on insulin release and insulin sensitivity was more pronounced in lean than in obese subjects, which resulted in greater deterioration of glucose tolerance in the lean population.     

Growth hormone stimulating the growth of arterial medial cells in vitro. Absence of effect of insulin

Earlier studies have shown a stimulatory effect of diabetic serum on the growth of rabbit aortic medial cell cultures. Growth media supplemented with normal serum with added insulin (50-2,000 muU./ml. serum) did not enhance the growth of the medial cell cultures. Control media containing serum from recent diabetics with low insulin concentration stimulated the growth (2p less than 0.01). Supplementation of normal serum with human growth hormone (final concentration 1-5 ng./ml. medium) resulted in a significant enhancement of growth (2p less than 0.005). The growth-promoting effect of growth hormone was not detectable with lower concentrations (0.5 ng. and 0.1 ng./ml. medium). The growth effect of the low concentration of growth hormone could not be augmented by increasing the concentration of glucose in the incubation medium. Growth hormone in an amount of 1 ng./ml. medium increased both the number of 3H-thymidine-labeled cells as identified by autoradiography and the number of mitotic bodies (2p less than 0.005 and 2 p less than 0.025). The present results demonstrate that the growth-stimulating factor(s) in diabetic human serum described earlier is not insulin but may well be growth hormone.     

Effect of somatostatin on metabolic and hormonal changes induced by nicotinic acid in insulin-dependent diabetics

The study investigated the respective influences of nicotinic acid and somatostatin on plasma concentrations of blood glucose, free fatty acids, glucagon, growth hormone and cortisol in insulin-dependent diabetic subjects. After administration of nicotinic acid alone, marked depression of plasma FFA was accompanied by significant increases of plasma glucagon, growth hormone and cortisol. The glucagon and growth hormone responses to nicotinic acid were significantly reduced when plasma FFA were raised by intravenous administration of heparin and triglycerides. Somatostatin alone induced a significant decrease in blood glucose, plasma glucagon and growth hormone concentrations. Plasma FFA remained unchanged. Somatostatin did not modify the nicotinic acid-induced fall in plasma FFA, but completely blocked the corresponding increments in glucagon and growth hormone. The cortisol rise was not altered by somatostatin. Rebound of glucagon and growth hormone levels were seen upon discontinuation of the somatostatin administration. These results demonstrate that the plasma FFA concentration plays a role in the regulation of glucagon and growth hormone secretion in insulin-dependent diabetics. Furthermore, they indicate that somatostatin, previously shown to be capable of negating the stimulatory effect of various factors on glucagon and growth hormone secretion, also affects the response of these hormones to FFA depression.     

The role of insulin and glucagon in the regulation of basal glucose production in the postabsorptive dog

The aim of the present experiments was to determine the role of insulin and glucagon in the regulation of basal glucose production in dogs fasted overnight. A deficiency of either or both pancreatic hormones was achieved by infusin somatostatin (1 mug/kg per min), a potent inhibitor of both insulin and glucagon secretion, alone or in combination with intraportal replacement infusions of either pancreatic hormone. Infusion of somatostatin alone caused the arterial levels of insulin and glucagon to drop rapidly by 72+/-6 and 81+/-8%, respectively. Intraportal infusion of insulin and glucagon at rates of 400 muU/kg per min and 1 ng/kg per min, respectively, resulted in the maintenance of the basal levels of each hormone. Glucose production was measured using tracer (primed constant infusion of [3-3H]glucose) and arteriovenous difference techniques. Isolated glucagon deficiency resulted in a 35+/-5% (P less than 0.05) rapid and sustained decrease in glucose production which was abolished upon restoration of the plasma glucagon level. Isolated insulin deficiency resulted in a 52+/-16% (P less than 0.01) increase in the rate of glucose production which was abolished when the insulin level was restored. Somatostatin had no effect on glucose production when the changes in the pancreatic hormone levels which it normally induces were prevented by simultaneous intraportal infusion of both insulin and glucagon. In conclusion, in the anesthetized dog fasted overnight; (a) basal glucagon is responsible for at least one-third of basal glucose production, (b) basal insulin prevents the increased glucose production which would result from the unrestrained action of glucagon, and (c) somatostatin has no acute effects on glucose turnover other than those it induces through perturbation of pancreatic hormone secretion. This study indicates that the opposing actions of the two pancreatic hormones are important in the regulation of basal glucose production in the postabsorptive state.     

Acute lowering of plasma fatty acids lowers basal insulin secretion in diabetic and nondiabetic subjects

The objective of this study was to determine whether basal plasma free fatty acid (FFA) concentrations affect basal insulin secretion rates (ISRs). Effects of FFA levels on basal ISRs were evaluated by lowering basal plasma FFA levels with nicotinic acid (NA) (100-150 mg p.o., q 30 min x 4 h) in type 2 diabetic patients and in normal volunteers. Lowering of FFAs (from approximately 600 to approximately 100 micromol/l) lowered ISRs in type 2 diabetic patients during isoglycemic clamping (from 139 to 101 pmol/min; -23%; P < 0.02) and euglycemic clamping (from 99 to 63 pmol/min; -36%; P < 0.03) and in normal subjects during euglycemic clamping (from 127 to 96 pmol/min; -25%; P < 0.03). In addition, peripheral insulin concentrations decreased by approximately 30% in diabetic and nondiabetic subjects. NA had no direct effect on ISRs; that is, NA did not change ISRs when plasma FFAs were prevented from decreasing with a lipid/heparin infusion. We concluded that 1) basal plasma FFAs exerted physiologically important, long-lasting effects supporting 25-33% of basal insulin secretion in nondiabetic and diabetic subjects; 2) basal plasma FFAs were responsible for some of the hyperinsulinemia in normoglycemic obese subjects; and 3) NA had no direct effect on insulin secretion.     

Effect of continuous subcutaneous insulin infusion with lispro on hepatic responsiveness to glucagon in type 1 diabetes

OBJECTIVE: People with type 1 diabetes frequently develop a blunted counterregulatory hormone response to hypoglycemia coupled with a decreased hepatic response to glucagon, and consequently, they have an increased risk of severe hypoglycemia. We have evaluated the effect of insulin lispro (Humalog) versus regular human insulin (Humulin R) on the hepatic glucose production (HGP) response to glucagon in type 1 diabetic patients on intensive insulin therapy with continuous subcutaneous insulin infusion (CSII). RESEARCH DESIGN AND METHODS: Ten subjects on CSII were treated for 3 months with lispro and 3 months with regular insulin in a double-blind randomized crossover study After 3 months of treatment with each insulin, hepatic sensitivity to glucagon was measured in each subject. The test consisted of a 4-h simultaneous infusion of somatostatin (450 microg/h) to suppress endogenous glucagon, regular insulin (0.15 mU x kg(-1) x min(-1)), glucose at a variable rate to maintain plasma glucose near 5 mmol/l, and D-[6,6-2H2]glucose to measure HGP During the last 2 h, glucagon was infused at 1.5 ng x kg(-1) x min(-1). Eight nondiabetic people served as control subjects. RESULTS: During the glucagon infusion period, free plasma insulin levels in the diabetic subjects were 71.7+/-1.6 vs. 74.8+/-0.5 pmol/l after lispro and regular insulin treatment, with plasma glucagon levels of 88.3+/-1.8 and 83.7+/-1.5 ng/l for insulin:glucagon ratios of 2.8 and 3.0. respectively (NS). However, plasma glucose increased to 9.2+/-1.1 mmo/l after lispro insulin compared with 7.1+/-0.9 mmol/l after regular insulin (P < 0.01), and the rise in HGP was 5.7 +/-2.8 micromol x kg(-1) x min(-1) after lispro insulin versus 3.1+/-2.9 micromol x kg(-1) x min(-1) after regular insulin treatment (P=0.02). In the control subjects, HGP increased by 10.7+/-4.2 micromol x kg(-1) x min(-1) under glucagon infusion. CONCLUSIONS: Insulin lispro treatment by CSII was associated with a heightened response in HGP to glucagon compared with regular human insulin. This suggests that insulin lispro increases the sensitivity of the liver to glucagon and could potentially decrease the risk of severe hypoglycemia.     

Heterogeneity of plasma glucagon. Circulating components in normal subjects and patients with chronic renal failure

Plasma immunoreactive glucagon (IRG) concentrations were measured in 36 patients with chronic renal failure (CRF) and 32 normal subjects. In addition, the components of circulating IRG were analyzed by gel filtration in the fasting state and after physiological stimuli. Fasting IRG was elevated (P less than 0.001) in CRF patients (534 +/- 32 pg/ml) compared with the levels found in healthy subjects (113 +/- 9 pg/ml). Oral glucose suppressed plasma IRG in CRF patients from a basal level of 568 +/- 52 to a nadir of 354 +/- 57 pg/ml (120 min). This degree of suppression (38%) was comparable to that found in normal subjects (basal = 154 +/- 20 to 100 +/- 23 pg/ml) at 120 min (35%). Intravenous infusion of arginine (250 mg/kg) resulted in a 71% rise in IRG in CRF patients and a 166% increase in normal subjects. Gel filtration of fasting plasma from CRF patients showed three major peaks. The earliest (A) was found in the void volume (mol wt greater than 40,000) and constituted 16.5 +/- 4.7% of the elution profile. The middle peak (B) eluted just beyond the proinsulin marker (approximately 9,000 mol wt) and constituted the largest proportion of the elution profile (56.5 +/- 3.4%). The third peak (C) coincided with the standard glucagon and [125I]glucagon markers (3,485 mol wt) and comprised 27.0 +/- 4% of the IRG profile. In contrast, only peaks A and C were found in fasting plasma of normal subjects (53.6 +/- 10.4% in A and 46.4 +/- 10.4 in C). After oral glucose, glucagon immunoreactivity in the 3,500 mol wt peak (C) was markedly suppressed, while the B peak in patients with CRF declined to a lesser extent. The A peak in both groups was unchanged. After an arginine infusion only the C peak increased in both groups of subjects. Gel filtration of plasma in 3 M acetic acid gave similar profiles to those obtained in glycine albumin buffer. Exposure of serum to trypsin indicated that the B and C peaks were digestible, while the A peak was resistant to the action of the enzyme. In one sample, peak C increased after a 2-h exposure of serum to trypsin. We conclude that circulating IRG in normal subjects and patients with CRF is heterogenous. The hyperglucagonemia of renal failure is largely due to an increase in IRG material of approximately 9,000 mol wt, consistent with proglucagon, although the 3,500 mol wt component is also considerably elevated (threefold). The significance of circulating IRG levels should be interpreted with caution until the relative biological activity of the three components is established.     

Effect of chlorpromazine on blood glucose and plasma insulin in man

In three groups of normal subjects and in one group of patients with latent diabetes mellitus a study has been made of the effects of chlorpromazine (CPZ) on blood glucose and plasma insulin. CPZ 75 mg/day for 7 days did not alter the plasma insulin response after oral glucose; nor did CPZ 50 mg/day for 7 days affect the glucose assimilation rate or insulin response to glucose injection. Infusion of CPZ 50 mg in 60 min slightly increased the basal blood glucose level but had no significant effect on basal plasma insulin. The insulin/glucose ratio after the end of the infusion was significantly higher than during the period of infusion of the drug. In latent diabetic patients CPZ infusion significantly diminished the insulin/glucose ratio during an intravenous glucose tolerance test. These results suggest that, whereas prolonged treatment with low doses of CPZ did not modify glucose tolerance and glucose-stimulated pancreatic response, higher acute doses of the drug may induce hyperglycaemia and can inhibit insulin secretion both in normal man and in patients with latent diabetes mellitus.     

Uptake and release of hormones and metabolites by tissues of exercising leg in man

To examine release of insulin from tissues of the exercising llin, growth hormone, cortisol, and circulating metabolites were studied in five men before, during, and after exercise on a bicycle ergometer at 60% of their maximum work capacity. At rest, insulin, growth hormone, and cortisol were taken up by leg tissues. During exercise arterial plasma insulin concentration fell, but cortisol and growth hormone levels rose; there was net release of insulin into venous blood but little change in uptake of cortisol and growth hormone. Insulin release persisted after exercise for 15-30 min. During exercise arterial concentrations and uptake of glucose and free fatty acids (FFA) increased. Examination of the changes in hormones and metabolites failed to identify any single hormonal or metabolic factor causing the observed reversal of insulin uptake with exercise.     

Influence of glucagon replacement on the hyperglycemic and hyperketonemic response to prolonged somatostatin infusion in normal man

Somatostatin was infused for 6 h into seven normal subjects with and without a replacement dose of glucagon. The addition of glucagon to somatostatin resulted in a 30-40% rise in plasma glucagon, whereas plasma insulin declined by 40-50% in both treatment groups. Plasma glucose and glucose production initially increased 2-fold with glucagon replacement, and subsequently declined by 2-3 h to levels comparable to those observed with somatostatin alone. After 6 h plasma glucose and glucose kinetics were no different whether or not glucagon was present. The rise in blood ketones after somatostatin was not exaggerated by glucagon replacement. We conclude that glucagon lack is not a modifying factor in the late hyperglycemic and hyperketonemic response to prolonged infusions of somatostatin.     

Control of hyperglycemia in adult diabetics by pulsed insulin delivery

Nine adult diabetic subjects were treated for two weeks by an intravenous insulin-delivery system that provided preprogramed five-hour pulses of insulin with each meal such that a normal diurnal pattern of plasma insulin was attained. Plasma insulin peaked at 800 per cent of basal and at approximately 45 minutes after the onset of each pulse. On day 14, mean plasma glucose (hourly sampling X 22) was 94 mg./100 ml., with a range of 66 to 125 mg./100 ml. Eighty-eight per cent of all values were between 50 and 150 mg./100 ml. The dose of insulin required correlated significantly with the degree of obesity. On the first posttreatment day, hourly plasma glucose remained significantly below pretreatment levels while the endogenous plasma insulin area increased 46 per cent above pretreatment values (p less than 0.01). Six of the patients still exhibited slight improvement in glucose tolerance for seven days while on diet but not on insulin treatment. It is concluded that insulin replacement, coordinated with meals in a physiologic manner, can virtually normalize plasma glucose even without feedback control of delivery rates. Definite but transient remission of beta-cell dysfunction may follow.     

Transient diabetes mellitus in a neonate. Evaluation of insulin, glucagon, and growth hormone secretion and management with a continuous low-dose insulin infusion

This neonate developed marked hyperglycemia four days after birth and required insulin therapy for eight weeks. During the acute phase of the disease, immunoreactive insulin was undetectable in portal venous serum. Neither tolbutamide nor theophylline administration significantly triggered insulin secretion. Somatostatin infusion inhibited growth hormone release but had no effect on plasma glucagon or blood glucose concentrations. At 2 1/2 months, two weeks after insulin withdrawal, the infant was still intolerant to an oral glucose load, insulin response was markedly delayed, and growth hormone secretion was paradoxical. At five months, the insulin, glucagon, and growth hormone responses to glucose and to somatostatin were normalized. Thus, in this patient, insulin secretion was transiently deficient. Peculiarities of glucagon and growth hormone secretion were also present but are more characteristic of this age group than of diabetes. The hyperglycemic state was managed by intraportal infusion of 0.1 to 0.2 IU regular insulin/kg/hour. This mode of insulin administration proved efficient, secure, and easy to manage.     

Insulin, glucagon, and somatostatin in normal physiology and diabetes mellitus

Studies are reviewed in which the roles of insulin and glucagon in normal physiology and in diabetes are examined. In normal man, glucose ingestion is accompanied by a rise in insulin and fall in glucagon and is primarily disposed of in the liver, an organ sensitive to both hormones. However, infusions of glucagon in physiologic amounts indicate that insulin secretion rather than glucagon inhibition is the primary factor determining glucose disposal. Furthermore, minor elevations in blood glucose elicit increments in insulin concentration and inhibition of hepatic glucose output in the absence of changes in plasma glucagon. The primary physiologic role of glucagon is to prevent the hypoglycemia that would otherwise accompany noncarbohydrate (protein)-mediated insulin secretion. In diabetic as well as normal patients the stimulatory effect of glucagon on hepatic glucose production is evanescent. Increases in glucagon or changes in the I/G ratio can bring about deterioration in glucose tolerance or in diabetic control only so long as absolute insulin deficiency is present or pharmacologic elevations in glucagon are produced. After somatostatin administration, prolonged hypoinsulinemia in normal subjects is observed to result in fasting hyperglycemia in the absence of basal glucagon secretion. In diabetic patients the improvement in postprandial hyperglycemia produced by somatostatin can be accounted for by its inhibitory action on carbohydrate absorption in the gastrointestinal tract. It is concluded that insulin deficiency is the primary pathophysiologic disturbance in diabetes. While glocagon may worsen the consequences of insulin lack, it is neither sufficient nor necessary for the development of diabetes.     

Effects of peroral alanine administration in lactating ewes with decreased availability of glucose

The metabolic effects of a phlorizin-induced drainage of glucose were studied in six lactating ewes with or without peroral alanine drenches in a study of crossover design. Phlorizin gave rise to a small, but significant, elevation of plasma beta-hydroxybutyrate. The plasma level of alanine decreased by about 30% due to the phlorizin injections and alanine was negatively correlated to beta-hydroxybutyrate. The plasma level of free fatty acids increased due to phlorizin. Plasma insulin and glucose concentrations were not significantly affected by phlorizin while glucagon level showed a small but significant increase. Peroral alanine drenches to phlorizin-treated ewes gave rise to a transitory elevation of alanine in plasma. The plasma level of free fatty acids was about 40% lower in phlorizin-treated ewes receiving alanine and beta-hydroxybutyrate tended to be lower (P < 0.08). We suggest that beta-hydroxybutyrate, apart from its function as an oxidative fuel, might play an important role by limiting glucose oxidation and protein degradation in skeletal muscles during periods of negative energy balance in ruminants. Furthermore, it is suggested that alanine supplementation decreases lipolysis and ketogenesis in lactating ewes.     

Non-insulin- and insulin-mediated glucose uptake in dairy cows

Four mid-lactation Holstein dairy cows (mean milk yield on day of experiments 26.1 kg/d) were used in a series of experiments to establish the contribution of non-insulin-mediated glucose uptake to total glucose uptake at basal insulin concentrations. A secondary objective was to determine whether somatostatin affects the action of infused insulin. In part I of the experiment a primed continuous infusion [6,6-2H]glucose (45.2 micrograms/kg per min) was begun at time 0 and continued for 5 h. After 3 h of [6,6-2H]glucose infusion (basal period) a primed continuous infusion of insulin (0.001 i.u./kg per min) was administered for 2 h. Coincidental with the insulin infusion, normal glucose was also infused in order to maintain the plasma glucose concentration at euglycaemia. Part II of the experiment was the same as part I except that somatostatin was infused for 2 h (0.333 micrograms/kg per min) instead of insulin. In part III of the experiment both insulin and somatostatin were infused for the final 2 h. Plasma insulin levels were increased by insulin infusion (to 0.1476 to 0.1290 i.u./l for parts I and III respectively) and were reduced by somatostatin infusion in part II (to 0.006 i.u./l) relative to the basal periods (mean 0.021 i.u./l). Glucose uptake during somatostatin infusion (2.50 mg/kg per min; part II) was 92.0% of that observed in the respective basal period (2.72 mg/kg per min). Circulating insulin levels were much lower than the dose of insulin that causes a half maximal effect on glucose uptake (0.06-0.10 i.u./l for ruminants); consequently insulin-mediated glucose uptake was probably absent in part II. Secondly, glucose uptake following insulin only infusion (4.05 mg/kg per min) was significantly lower than that observed when insulin plus somatostatin was infused (4.69 mg/kg per min), indicating that somatostatin either directly or indirectly enhanced the action of insulin on glucose uptake.     

Counterregulation by epinephrine and glucagon during insulin-induced hypoglycemia in the conscious dog

We assessed the combined role of epinephrine and glucagon in regulating gluconeogenic precursor metabolism during insulin-induced hypoglycemia in the overnight-fasted, adrenalectomized, conscious dog. In paired studies (n = 5), insulin was infused intraportally at 5 mU.kg-1.min-1 for 3 h. Epinephrine was infused at a basal rate (B-EPI) or variable rate to simulate the normal epinephrine response to hypoglycemia (H-EPI), whereas in both groups the hypoglycemia-induced rise in cortisol was simulated by cortisol infusion. Plasma glucose fell to approximately 42 mg/dl in both groups. Glucagon failed to rise in B-EPI, but increased normally in H-EPI. Hepatic glucose release fell in B-EPI but increased in H-EPI. In B-EPI, the normal rise in lactate levels and net hepatic lactate uptake was prevented. Alanine and glycerol metabolism were similar in both groups. Since glucagon plays little role in regulating gluconeogenic precursor metabolism during 3 h of insulin-induced hypoglycemia, epinephrine must be responsible for increasing lactate release from muscle, but is minimally involved in the lipolytic response. In conclusion, a normal rise in epinephrine appears to be required to elicit an increase in glucagon during insulin-induced hypoglycemia in the dog. During insulin-induced hypoglycemia, epinephrine plays a major role in maintaining an elevated rate of glucose production, probably via muscle lactate release and hepatic lactate uptake.