In vitro effects of glycosylated insulin and glucagon in perfused liver of the rat.

Using perfused liver of the rat, the hepatic uptake of glycosylated insulin (GI) and glucagon (GG) and its effects on hepatic glucose output were investigated. Insulin and glucagon were glycosylated in ambient high glucose concentration, and GI80 or GG80 (insulin or glucagon incubated with 0.08% glucose), GI350 or GG350 (incubated with 0.35% glucose), and GI1000 or GG1000 (incubated with 1% glucose) were prepared. The liver was perfused with the medium containing 1000 microU/ml insulin and 200 pg/ml glucagon or 200 microU/ml insulin and 1000 pg/ml glucagon. The fractional uptake of insulin or glucagon by perfused liver was not significantly altered by the glycosylation. In the liver perfused with 1000 microU/ml insulin and 200 pg/ml glucagon, glucose output was not changed by the glycosylation of the hormones, while in the liver perfused with 200 microU/ml insulin and 1000 pg/ml glucagon, GI1000 reduced its biological activity, as reflected by insulin-mediated decrease in glucose output. These results suggest that in the liver insulin incubated with markedly high concentration of glucose reduces its biological activity at a physiological concentration in the presence of high concentration of glucagon.     

Effect of insulin on glucose uptake in near-term fetal lambs

Glucose clamp experiments were performed in 27 chronically catheterized, late-gestation fetal lambs in order to measure the effect of fetal insulin concentration on fetal glucose uptake at a constant glucose concentration. Fetal arterial blood glucose concentration was measured over a 30-min control period and then maintained at the control value by a variable glucose infusion into the fetus while insulin was infused at a constant rate into the fetus. Plasma insulin concentration increased from 21 +/- 10 (SD) to 294 +/- 179 (SD) microU X ml-1. The exogenous glucose infusion rate necessary to maintain constant glycemia during the plateau hyperinsulinemia averaged 4.3 +/- 1.6 (SD) mg X min-1 X kg-1. In a subset of 13 animals, total fetal exogenous glucose uptake (FGU; sum of glucose uptake from the placenta via the umbilical circulation plus the steady-state exogenous glucose infusion rate) was measured during the control and hyperinsulinemia period. FGU was directly related to insulin concentration (y = 4.24 + 0.07x) at insulin levels less than 100 microU/ml and increased 132% above control at insulin levels above 100 microU/ml. Hyperinsulinemia did not affect fetal glucose uptake from the placenta via the umbilical circulation. These studies demonstrate that insulin concentration is a major factor controlling glucose uptake in the near-term fetal lamb, and that an increase of fetal insulin does not affect the transport of glucose to the fetus from the placenta.     

In vitro effects of glycosylated insulin in perfused liver and hindquarter in rats.

Using the perfused liver and hindquarter of the rat, the uptake of glycosylated insulin and its effect on glucose output were investigated. Insulin was glycosylated in ambient high glucose concentration, and glycosylated insulin GI80 (insulin incubated with 0.08% glucose), GI350 (incubated with 0.35% glucose), and GI1000 (incubated with 1% glucose) were prepared. The liver and hindquarter were perfused with nonglycosylated insulin (N-GI) or glycosylated insulin at a concentration of 100 or 1000 microU/ml. There were no significant differences in the fractional uptake of insulin by perfused liver and hindquarter despite glycosylation. Insulin-induced decrement in glucose output was significantly lower in the liver perfused with GI1000 than that in the liver perfused with N-GI, GI80, and GI350 at an insulin concentration of 100 microU/ml. There were no significant differences in insulin-induced decrement in glucose output between the hindquarter perfused with N-GI, GI80, GI350, and GI1000. These results suggest that when insulin (100 microU/ml) is incubated with a markedly elevated concentration of glucose (1000 mg/dl) its biological activity is reduced in the liver, but not in the hindquarter.     

Comparison of local and systemic effects of insulin on myocardial glucose extraction in ischemic heart disease

Physiological increases in circulating insulin level significantly increase myocardial glucose uptake in vivo. To what extent this represents a direct insulin action on the heart or results indirectly from reduction in circulating concentrations of free fatty acids (FFA) is uncertain. To examine this, we measured myocardial glucose, lactate, and FFA extraction in 10 fasting men (ages 49-76 yr) with stable coronary artery disease during sequential intracoronary (10 mU/min, coronary plasma insulin = 140 +/- 20 microU/ml) and intravenous (100 mU/min, systemic plasma insulin = 168 +/- 26 microU/ml) insulin infusion. Basally, hearts extracted 2 +/- 2% of arterial glucose and extracted 27 +/- 6% of FFA. Coronary insulin infusion increased glucose extraction to 5 +/- 3% (P < 0.01 vs. basal) without changing plasma FFA or heart FFA extraction. Conversion to intravenous infusion lowered plasma FFA by approximately 50% and heart FFA extraction by approximately 75%, increasing heart glucose extraction still further to 8 +/- 3% (P < 0. 01 vs. intracoronary). This suggests the increase in myocardial glucose extraction observed in response to an increment in systemic insulin concentration is mediated equally by a reduction in circulating FFA and by direct insulin action on the heart itself. Coronary insulin infusion increased myocardial lactate extraction as well (from 20 +/- 10% to 29 +/- 9%, P < 0.05), suggesting the local action may include stimulation of a metabolic step distal to glucose transport and glycolysis.     

Fetal insulin and placental 3-O-methyl glucose clearance in near-term sheep

It is difficult, if not impossible, to measure the placental transfer of glucose directly because of placental glucose consumption and the low A-V glucose difference across the sheep placenta. We have approached the problem of quantifying placental hexose transfer by using a nonmetabolized glucose analogue (3-O-methyl glucose) which shares the glucose transport system. We have measured the clearance by using a multisample technique permitting least squares linear computing to avoid the errors implicit in the Fick principle. The placental clearance of 3-O-methyl glucose was measured in the control condition and after the administration of insulin to the fetal circulation. A glucose clamp technique was used to maintain constant transplacental glucose concentrations throughout the duration of the experiment. A control series was performed in which the only intervention was the infusion of normal saline. In these experiments the maternal and fetal glucose concentrations remained constant as did the volume of distribution of 3-O-methyl glucose in the fetus. The maternal insulin concentration remained constant and fetal insulin concentration changed from 11 +/- 2 microU/ml to 355 +/- 51 microU/ml (P less than 0.01). In the face of this large increase in fetal plasma insulin, there was no change in the placental clearance of 3-O-methyl glucose. In the control condition the clearance was 14.1 +/- 1.0 ml/min per kg and this was 13.8 +/- 1.0 ml/min per kg in the high insulin condition. Fetal insulin may change placental glucose flux by decreasing fetal plasma glucose concentrations but does not do so by changing the activity of the glucose transport system.     

The effect of magnesium deficiency on glucose stimulated insulin secretion in rats

Weanling Sherman rats were pair-fed for 8 days on a control or a magnesium deficient diet containing 70.5% sucrose. After a 12-hour fast, the rats were injected intraperitoneally with glucose (250 mg/100 g body weight) and arterial blood was drawn at 0, 15, 30, 60, 90 minutes after injection. Before glucose loading, in magnesium deficient rats, plasma magnesium levels were significantly increased. The plasma triglyceride concentration was significantly higher in magnesium deficient rats compared to controls. After glucose loading, in the control group, the plasma insulin concentrations increased to 67.9 +/- 5.8 microU/ml at 15 minutes and returned to pretreatment levels by 30 minutes; in the magnesium-deficient rats, the plasma insulin levels were significantly lower at 15 minutes 32.9 +/- 5.6 microU/ml (P less than 0.01) and returned more slowly to the pre-challenge level. No significant differences were observed in plasma glucose levels between the two groups of rats.     

Transient glucose intolerance during attacks of thyrotoxic periodic paralysis

In a 19-year-old Japanese male (case 1) with thyrotoxic periodic paralysis (TPP), an increase of plasma glucose concentration together with abnormally high levels of serum immunoreactive insulin (IRI) was observed preceding a spontaneous attack of paralysis. Therefore, the plasma glucose, glucagon, epinephrine, norepinephrine, serum IRI, growth hormone and cortisol levels, and the erythrocyte insulin receptors were measured in case 1 and a 40-year-old Japanese male (case 2) with TPP during attacks of paralysis induced by prolonged glucose loading. In case 1, the serum IRI concentration was elevated to the extraordinarily high level of 655.0 microU/ml at the beginning of paralysis, and at that time, the plasma glucose concentration was 147 mg/dl. However, when paralysis was not induced by a similar glucose loading during methimazole treatment, the serum IRI and plasma glucose levels at the corresponding time after glucose loading were 20.9 microU/ml and 87 mg/dl, respectively. Furthermore, the affinity of the erythrocyte insulin receptors was decreased during the attack. In case 2, plasma glucose and serum IRI concentrations were increased in accordance with the initiation of paralysis although the blood levels of hormones counteracting insulin were not significantly changed. These findings suggest that there is something interacting with the normal action of the insulin in the early phase of paralysis.     

Sensitivity and responsiveness of glucose output to insulin in isolated perfused liver from dexamethasone-treated rats

To elucidate insulin action on hepatic glucose output (glycogenolysis) in the state exposed to an excess glucocorticoid, the fed rat liver was isolated and cyclically perfused with a medium containing 5 mM glucose and various concentrations of insulin. The rat was subcutaneously injected with 1 mg/kg of dexamethasone (Dex) for 7 days. Dex-treated rats showed marked increases of serum insulin and plasma glucose level compared with those in control rats. Hepatic glycogen contents in Dex group were markedly increased compared with those in control (115 +/- 5 and 28 +/- 4 mg/g, respectively). Insulin extraction rate in the perfused liver was not different between control and Dex group. Perfusate glucose level after 60 min perfusion was much higher in the Dex-treated rat liver than that of the control at 0 microU/ml insulin (34.5 +/- 2.5 vs 23.0 +/- 2.0 mM, P less than 0.01), and reduced to the nadir level (19.0 +/- 3.0 and 13.0 +/- 1.5 mM, respectively) at 100 microU/ml insulin in both groups, i.e., the decreasing rate in perfusate glucose level was not different between Dex and control group (43% and 44%, respectively). These results suggest that Dex-treatment augments hepatic glucose output, but does not affect the sensitivity and responsiveness of that to insulin.     

Kupffer cells play a major role in insulin-mediated hepatic glucose uptake in vivo.

The effect of insulin on the in vivo glucose utilization by different hepatic cells was investigated using the euglycemic, hyperinsulinemic clamp, combined with the 2-deoxyglucose tracer technique. Rats were infused with insulin at a rate of 2.8 or 9.0 mU/min/kg for 220 min, resulting in plasma concentrations of the hormone of about 80 microU/ml and 340 microU/ml, respectively. Glucose use by the whole liver was elevated by more than 200% following insulin. However, glucose uptake by the parenchymal cells was only elevated by 50-60%. By contrast nonparenchymal cells were more responsive to insulin. Glucose uptake by endothelial cells was increased 100% and Kupffer cells displayed the most marked response to insulin showing a 3- to 6-fold increase in glucose uptake. These data indicate that the sinusoidal nonparenchymal cells are the major sites of the insulin-mediated increased glucose utilization by the liver.     

The B2 receptor of bradykinin is not essential for the post-exercise increase in glucose uptake by insulin-stimulated mouse skeletal muscle

Bradykinin can enhance skeletal muscle glucose uptake (GU), and exercise increases both bradykinin production and muscle insulin sensitivity, but bradykinin's relationship with post-exercise insulin action is uncertain. Our primary aim was to determine if the B2 receptor of bradykinin (B2R) is essential for the post-exercise increase in GU by insulin-stimulated mouse soleus muscles. Wildtype (WT) and B2R knockout (B2RKO) mice were sedentary or performed 60 minutes of treadmill exercise. Isolated soleus muscles were incubated with [3H]-2-deoxyglucose +/-insulin (60 or 100 microU/ml). GU tended to be greater for WT vs. B2RKO soleus with 60 microU/ml insulin (P=0.166) and was significantly greater for muscles with 100 microU/ml insulin (P<0.05). Both genotypes had significant exercise-induced reductions (P<0.05) in glycemia and insulinemia, and the decrements for glucose (approximately 14 %) and insulin (approximately 55 %) were similar between genotypes. GU tended to be greater for exercised vs. sedentary soleus with 60 microU/ml insulin (P=0.063) and was significantly greater for muscles with 100 microU/ml insulin (P<0.05). There were no significant interactions between genotype and exercise for blood glucose, plasma insulin or GU. These results indicate that the B2R is not essential for the exercise-induced decrements in blood glucose or plasma insulin or for the post-exercise increase in GU by insulin-stimulated mouse soleus muscle.     

Effects of insulin on the metabolism of acetate, beta-hydroxybutyrate and triglycerides by the bovine mammary gland

The effect of insulin on net metabolism of acetate, beta-hydroxybutyrate, glucose and triglycerides by the bovine mammary gland was determined using the glucose clamp technique. Elevation of insulin concentrations in plasma by 50 microU/ml was not associated with significant changes in venoarterial concentration differences and extraction ratios ((A-V)/A). Insulin does not appear to alter the metabolism of acetate, beta-hydroxybutyrate, glucose and triglycerides by direct effects on the mammary gland.     

Levonorgestrel and norethindrone alter insulin action on skeletal muscle of the female rat

Prospective studies of women receiving oral contraceptives suggest that the progestin component may induce insulin resistance and variable deterioration of glucose tolerance. Because the tissue sites and nature of this insulin antagonism are not well-defined, we studied the effects of two parenterally administered progestins, levonorgestrel (NG) and norethindrone (NE), on insulin-regulated glucose uptake and phenylalanine release by the perfused rat hindquarter. Female rats were injected sc for 14 days with NG or NE (10 or 30 micrograms/kg/day). Low-dose NG and high-dose NE approximate the per kg dose received by women taking a high-dose progestin oral contraceptive. Phenylalanine release and glucose uptake (nmole/min/g) by the perfused hindquarters were calculated from the A-V difference for each. Progestin treatment (30 micrograms/kg/d) significantly reduced phenylalanine release from hindquarters perfused without exogenous insulin. Hindquarters from the high dose NG and low and high dose NE rats perfused with insulin (100 microU/ml) released 22% less phenylalanine than control rats perfused with the same insulin concentration (P less than 0.01) but the net suppression below baseline was similar in the control and steroid-treated groups. High-dose progestin treatment did not alter glucose uptake by hindquarters perfused without exogenous insulin. Insulin (100 microU/ml) increased glucose uptake by hindquarters of control and progestin-treated rats as compared to animals in the same treatment group perfused without exogenous insulin (P less than 0.01). High dose NE impaired insulin-stimulated glucose uptake 24% below values of the control group (P less than 0.01). The other NE and NG doses had no effect.(ABSTRACT TRUNCATED AT 250 WORDS)     

Impact of continuous and pulsatile insulin delivery on net hepatic glucose uptake

The pancreas releases insulin in a pulsatile manner; however, studies assessing the liver's response to insulin have used constant infusion rates. Our aims were to determine whether the secretion pattern of insulin [continuous (CON) vs. pulsatile] in the presence of hyperglycemia 1) influences net hepatic glucose uptake (NHGU) and 2) entrains NHGU. Chronically catheterized conscious dogs fasted for 42 h received infusions including peripheral somatostatin, portal insulin (0.25 mU x kg(-1) x min(-1)), peripheral glucagon (0.9 ng x kg(-1) x min(-1)), and peripheral glucose at a rate double the glucose load to the liver. After the basal period, insulin was infused for 210 min at either four times the basal rate (1 mU x kg(-1) x min(-1)) or an identical amount in pulses of 1 and 4 min duration, followed by intervals of 11 and 8 min (CON, 1/11, and 4/8, respectively) in which insulin was not infused. A variable peripheral glucose infusion containing [3H]glucose clamped glucose levels at twice the basal level ( approximately 200 mg/dl) throughout each study. Hepatic metabolism was assessed by combining tracer and arteriovenous difference techniques. Arterial plasma insulin (microU/ml) either increased from basal levels of 6 +/- 1 to a constant level of 22 +/- 4 in CON or oscillated from 5 +/- 1 to 416 +/- 79 and from 6 +/- 1 to 123 +/- 43 in 1/11 and 4/8, respectively. NHGU (-0.8 +/- 0.3, 0.4 +/- 0.2, and -0.9 +/- 0.4 mg x kg(-1) x min(-1)) and net hepatic fractional extraction of glucose (0.04 +/- 0.01, 0.04 +/- 0.01, and 0.05 +/- 0.01 mg x kg(-1) x min(-1)) were similar during the experimental period. Spectral analysis was performed to assess whether a correlation existed between the insulin secretion pattern and NHGU. NHGU was not augmented by pulsatile insulin delivery, and there is no evidence of entrainment in hepatic glucose metabolism. Thus the loss of insulin pulsatility per se likely has little or no impact on the effectiveness of insulin in regulating liver glucose uptake.     

Liver glycogen and plasma insulin and glucagon levels in food- and water-deprived black-tailed prairie dogs (Cynomys ludovicianus)

1. Liver glycogen levels and plasma levels of insulin and glucagon were measured in fed and in food- and water-deprived prairie dogs. 2. Liver glycogen values decreased from 45.5 to 12.4 mg/g (73%) after 21 days of food and water deprivation, while a 24-hr fast resulted in a liver glycogen value of 47.5 mg/g. 3. Rat liver glycogen values decreased from 45.6 to 2.3 mg/g (95%) after a 24-hr fast. 4. Prairie dog plasma insulin values were 69.2, 15.8 and 25.4 microU/ml in fed, and in 24-hr and 32-day food- and water-deprived animals, respectively. 5. Prairie dog plasma glucagon levels were 57.0 and 38.4 microU/ml in fed and in 32-day food- and water-deprived animals. 6. Plasma values for glucose, urea nitrogen, acetone and triglyceride agreed with previously published results. 7. We conclude that it is possible that the maintenance of liver glycogen levels in food- and water-deprived prairie dogs may be correlated with a smaller decrease in plasma insulin levels, relative to other species, and with a decrease in plasma glucagon levels.     

Insulin-induced alterations in amino acid metabolism in the fetal lamb

To investigate the role of insulin in modulation of fetal amino acid metabolism, insulin infusions were performed in 10 chronically-catheterized fetal lambs. Fetal insulin infusion caused a dose related fall in the arterial blood concentrations of 13 of 15 amino acids studied as well as a 15-25% decrease in total amino acid concentration. Fetal lambs exhibited a biphasic response of umbilical total amino acid uptake when compared to fetal blood insulin concentration, i.e., at achieved fetal insulin concentrations less than 100 microU/ml, umbilical uptake of 9 specific amino acids as well as summed amino acid uptake from the umbilical circulation were depressed, but at insulin concentrations of 100-350 microU/ml, amino acid uptakes were similar to or above control values. Insulin infusion also caused a drastic diminution in the rate of fetal urea excretion. These findings suggest that insulin acts in the fetus to depress amino acid catabolism, thus altering amino acid extraction and uptake. Depressed protein catabolism with or without enhanced amino acid uptake would have the theoretical effect of stimulation of net protein synthesis with a shift toward use of nonprotein substrates for energy purposes.     

Serum immunoreactive insulin levels in intact and regenerating postmetamorphic Xenopus laevis

In order to confirm the presence of immunoreactive insulin (IRI) in the serum of postmetamorphic Xenopus laevis, radioimmunoassay (RIA) methods were used. The concentration of hormone found in samples of blood serum taken from nonanaesthetized intact male and female animals by the guillotine method was 10.46 +/- 0.76 microU/ml. Significantly higher IRI concentrations were found in our intact animals anaesthetized in MS 222 at pH 3.5 (21.9 microU/ml) compared with intact controls anaesthetized in MS 222 adjusted to pH 7.0 (14.4 microU/ml). During the wound-healing stage subsequent to forelimb amputation in the experimental cases (0 hours to 3 days) anaesthetized in MS 222 pH 7.0, there were intervals of significantly elevated serum IRI followed by a period of decreased IRI concentration compared with the levels in anaesthetized (MS 222 pH 7.0) and nonanaesthetized intact controls. These fluctuations were due, presumably, to stress caused by amputational injury and/or anaesthetic. Serum IRI increased steadily from 3 to 14 days postamputation then remained stable for the balance of the regeneration period (28 days) compared with nonanesthetized intact controls. A positive correlation was found between immunoreactive insulin and glucose levels in the serum of our animals. However, no correlation exists between serum IRI levels and serum osmolality in the data.     

The relationship between plasma concentration and disappearance rate of immunoreactive insulin in the conscious dog

The relationship between plasma concentration and disappearance (infusion) rate of insulin was determined during infusion of insulin via the portal circulation of 14 normal euglycaemic dogs when somatostatin was infused to block endogenous insulin secretion. The relationship could be represented by one straight line over the plasma immunoreactive insulin range 0 to 110 microU/ml (r = 0.99) but above 110 microU/ml the fractional insulin disappearance rate declined. The results indicate the existence in the dog of a saturable pathway of insulin degradation that could conceivably be located in liver and which may become saturated only at insulin concentrations in the portal vein exceeding approximately 330 microU/ml.     

In vitro simulation of calorie restriction-induced decline in glucose and insulin leads to increased insulin-stimulated glucose transport in rat skeletal muscle

In vivo calorie restriction [CR; consuming 60% of ad libitum (AL) intake] induces elevated insulin-stimulated glucose transport (GT) in skeletal muscle. The mechanisms triggering this adaptation are unknown. The aim of this study was to determine whether physiological reductions in extracellular glucose and/or insulin, similar to those found with in vivo CR, were sufficient to elevate GT in isolated muscles. Epitrochlearis muscles dissected from rats were incubated for 24 h in media with glucose (8 mM) and insulin (80 microU/ml) at levels similar to plasma values of AL-fed rats and compared with muscles incubated with glucose (5.5 mM) and/or insulin (20 microU/ml) at levels similar to plasma values of CR rats. Muscles incubated with CR levels of glucose and insulin for 24 h had a subsequently greater (P < 0.005) GT with 80 microU/ml insulin and 8 mM [(3)H]-3-O-methylglucose but unchanged GT without insulin. Reducing only glucose or insulin for 24 h or both glucose and insulin for 6 h did not induce altered GT. Increased GT after 24-h incubation with CR levels of glucose and insulin was not attributable to increased insulin receptor tyrosine phosphorylation, Akt serine phosphorylation, or Akt substrate of 160 kDa phosphorylation. Nor did 24-h incubation with CR levels of glucose and insulin alter the abundance of insulin receptor, insulin receptor substrate-1, GLUT1, or GLUT4 proteins. These results provide the proof of principle that reductions in extracellular glucose and insulin, similar to in vivo CR, are sufficient to induce an increase in insulin-stimulated glucose transport comparable to the increase found with in vivo CR.     

Rates and tissue sites of noninsulin- and insulin-mediated glucose uptake in diabetic rats.

The purpose of the present study was to determine whether streptozotocin-induced diabetes alters the rates and tissue distribution of insulin-mediated glucose uptake (IMGU) and noninsulin-mediated glucose uptake (NIMGU). In vivo glucose disposal was assessed using the tracer [U-14C]-2-deoxyglucose technique in chronically catheterized conscious rats. For nondiabetic animals, rates of NIMGU were determined during severe insulinopenia (less than 5 microU/ml), induced by the infusion of somatostatin, under both euglycemic (6 mM) and hyperglycemic (17 mM) conditions. In diabetic rats, in which a severe insulin deficiency already existed, NIMGU was determined under basal hyperglycemic conditions and during euglycemic conditions produced by inhibiting hepatic glucose output. IMGU was determined in both groups using the euglycemichyperinsulinemic clamp technique. Glucose uptake was consistently higher (50-280%) in all tissues removed from diabetic rats under basal conditions, compared with tissues from control animals in the basal state. When control animals were rendered insulinopenic, glucose uptake by the skeletal muscle, heart, and diaphragm was reduced 30-60%, indicating that the uptake by these tissues occurred by both insulin- and noninsulin-mediated mechanisms. Glucose disposal by the other tissues sampled was entirely due to NIMGU under basal conditions. When blood glucose levels were elevated from 6 to 17 mM in control animals, NIMGU increased in all tissues (60-280%) except the brain. Rates of NIMGU were essentially identical between control and diabetic animals, under either euglycemic or hyperglycemic conditions, when glucose uptake was determined under the same steady-state plasma glucose levels. In contrast to the normal rate of NIMGU by muscle, IMGU by the skeletal muscle and heart from diabetic rats were reduced under mild hyperinsulinemic conditions (100 microU/ml), compared with control animals. Furthermore, in response to a maximal, stimulating dose of insulin (500 microU/ml), IMGU was impaired in the diaphragm, liver, lung, spleen, skin, and kidney removed from diabetic animals. These results indicate that the majority of glucose disposal under basal postabsorptive conditions occurs by NIMGU in both control and diabetic rats. Furthermore, while IMGU was selectively impaired in this model of insulin-dependent diabetes, the rates and tissue distribution of NIMGU were unaltered when glucose uptake was determined under similar plasma glucose levels.     

Effect of sparteine sulfate on insulin secretion in normal men

This study aimed at evaluating the influence of sparteine sulfate either upon basal plasma glucose and insulin or glucose-induced insulin secretion in normal man. Thirteen overnight fasted volunteers took part in this study; five of them were submitted to sparteine sulfate bolus (15 mg in 10 ml of saline solution) followed by a slow infusion (90 mg/100 ml X 60 min) and eight subjects underwent two different glucose pulses (20 gr. i.v.) in absence or in presence of sparteine, infused as described above. In basal conditions, along with sparteine infusion, plasma glucose showed a progressive and significant decrease (P less than 0.0001) and plasma insulin was significantly higher from min 10 to 120' (P less than 0.0005-0.001). Even during the glucose-induced insulin secretion, in the presence of sparteine infusion, plasma glucose levels were significantly lower while plasma insulin levels were significantly higher when compared to those observed after glucose alone. The acute insulin response (AIR) was 42 +/- 10 microU/ml after glucose alone vs 67 +/- 9 microU/ml after glucose plus sparteine (P less than 0.05). Total insulinemic areas were significantly different being 1410 +/- 190 vs 2250 +/- 310 microU/ml/min (P less than 0.001) during glucose and glucose plus sparteine infusion, respectively. This study thereby, demonstrates that in normal man sparteine sulfate, administrated by intravenous infusion, is able to increase either basal or glucose-induced insulin secretion.