The impact of pegvisomant treatment on substrate metabolism and insulin sensitivity in patients with acromegaly

CONTEXT: Pegvisomant is a specific GH receptor antagonist that is able to normalize serum IGF-I concentrations in most patients with acromegaly. The impact of pegvisomant on insulin sensitivity and substrate metabolism is less well described. PATIENTS AND METHODS: We assessed basal and insulin-stimulated (euglycemic clamp) substrate metabolism in seven patients with active acromegaly before and after 4-wk pegvisomant treatment (15 mg/d) in an open design. RESULTS: After pegvisomant, IGF-I decreased, whereas GH increased (IGF-I, 621 +/- 82 vs. 247 +/- 33 microg/liter, P = 0.02; GH, 5.3 +/- 1.5 vs. 10.8 +/- 3.3 microg/liter, P = 0.02). Basal serum insulin and plasma glucose levels decreased after treatment (insulin, 54 +/- 5.9 vs. 42 +/- 5.3 pmol/liter, P = 0.001; glucose, 5.7 +/- 0.1 vs. 5.3 +/- 0.0 mmol/liter, not significant), whereas palmitate kinetics were unaltered. During the clamp, the glucose infusion rate increased after pegvisomant (3.1 +/- 0.5 vs. 4.4 +/- 0.6 mg/kg.min, P = 0.02), whereas the suppression of endogenous glucose production tended to increase (0.7 +/- 0.0 vs. 0.5 +/- 0.1 mg/kg.min, not significant). Total resting energy expenditure decreased after pegvisomant treatment (1703 +/- 109 vs. 1563 +/- 101 kcal/24 h, P = 0.03), but the rate of lipid oxidation did not change significantly. CONCLUSIONS: 1) Pegvisomant treatment for 4 wk improves peripheral and hepatic insulin sensitivity in acromegaly. 2) This is associated with a decrease in resting energy expenditure, whereas free fatty acid metabolism is unaltered. 3) The data support the important direct effects of GH on glucose metabolism and add additional benefits to pegvisomant treatment for acromegaly.     

Short-term effects of growth hormone on fuel oxidation and regional substrate metabolism in normal man

Primarily by increasing the availability of lipid intermediates, GH is likely to have profound effects on substrate consumption rates. To examine the short term actions of GH on glucose turnover, fuel oxidation and regional forearm metabolism, six normal volunteers were each studied twice for 5.5 h after having received a 4-h infusion of GH (20 ng/kg.min) or saline. GH induced slightly falling plasma glucose levels, acute 40-50% decreases in forearm glucose uptake, and no change in glucose turnover. Furthermore, substantial increases in circulating concentrations and forearm uptake of nonesterified fatty acids and 3-hydroxybutyrate were recorded. Although GH infusion was followed by a 50% reduction of forearm alanine release hepatic nitrogen excretion seemed unaffected. Energy expenditure was not influenced by GH, but the non-protein respiratory exchange ratio decreased from a basal value of 0.778 +/- 0.008 to 0.732 +/- 0.007 after GH treatment (P less than 0.05). Correspondingly, lipid oxidation increased from 1.20 +/- 0.06 to 1.48 +/- 0.09 mg/kg.min, and glucose oxidation decreased from 0.97 +/- 0.12 to 0.39 +/- 0.06 mg/kg.min (P less than 0.05). Nonoxidative glucose utilization tended to increase. These data indicate that GH, by promoting lipid utilization and decreasing glucose oxidation, diminishes the need for gluconeogenesis and, therefore, could be protein preserving in the long term. Overall, we found no evidence of GH having acute insulin-like effects on glucose metabolism. GH appears to increase glucose storage, leaving total energy expenditure unaffected.     

Impact of octreotide, a long-acting somatostatin analogue, on glucose tolerance and insulin sensitivity in acromegaly

OBJECTIVE: We aimed to investigate the impact of a long-acting somatostatin analogue, octreotide, on glucose tolerance and on insulin sensitivity in acromegaly. DESIGN: We performed a non-randomized controlled trial. PATIENTS: Seven patients with active acromegaly were assessed before and during octreotide therapy given in a dose of 500 micrograms three times daily subcutaneously. MEASUREMENTS: The effects of octreotide on carbohydrate metabolism were assessed by performing a glucose tolerance test and a euglycaemic hyperinsulinaemic clamp. These latter tests were undertaken 8 hours after the last dose, allowing GH and glucagon to return to pretreatment levels during the study. RESULTS: Octreotide significantly reduced (P less than 0.05) mean +/- SEM 12-h GH (from 42 +/- 13 to 10 +/- 3 mIU/I) and IGF-I (from 4.2 +/- 0.5 to 2.1 +/- 0.5 U/ml) concentrations. Glucose tolerance was normalized in four of five patients with impaired glucose tolerance without a significant change in mean insulin concentrations. The improvement in fasting and mean blood glucose during glucose tolerance testing was dependent on the pretherapy blood glucose concentrations (r = -0.95, P = 0.002). The glucose infusion rate during the hyperinsulinaemic (5 U/h) clamp was significantly increased (P less than 0.05, 15.3 +/- 1.8 vs 24.2 +/- 5.4 mumol/kg min) following octreotide treatment. Insulin infusion during the glucose clamp completely suppressed hepatic glucose production during but not before octreotide treatment (7.9 +/- 2.4 vs 0.7 +/- 2.2 mumol/kg min, P = 0.02). Insulin-mediated stimulation of peripheral glucose uptake was unaffected by treatment. Mean GH and glucagon levels during both clamp studies were not significantly different. CONCLUSIONS: Octreotide improves whole body insulin sensitivity by an increased ability of insulin to suppress hepatic glucose production without affecting the substantial impairment of peripheral insulin action. Octreotide has beneficial effects on carbohydrate metabolism in acromegalic patients with glucose intolerance.     

Effects of growth hormone on insulin sensitivity and forearm metabolism in normal man

To elucidate the short-term actions of growth hormone on insulin sensitivity and forearm metabolism, we have studied six normal male subjects receiving a 6-h hyperinsulinaemic euglycemic clamp with and without a concomitant 4-h growth hormone infusion. When infused, serum growth hormone rose to 25 +/- 4 mU/l and during administration of insulin serum insulin increased by 11 +/- 1 mU/l. During euglycemic clamp, administration of growth hormone decreased forearm glucose uptake after 180 min and onward (240 min 0.216 +/- 0.031 vs 0.530 +/- 0.090 mg/100 ml/min, p less than 0.05). Glucose infusion rate (240 min 2.83 +/- 0.24 vs 4.35 +/- 0.28 mg.kg-1.min-1, p less than 0.05) and glucose disposal rate (240 min 3.57 +/- 0.17 vs 4.00 +/- 0.15 mg.kg-1.min-1, p less than 0.05) also decreased. Growth hormone persistently increased hepatic glucose production after 120 min. After 210 min, all circulating lipid intermediates increased slightly. The decrease in forearm glucose uptake and glucose infusion rate and the increase in hepatic glucose production was observed before there was any detectable increase in circulating levels and forearm uptake of lipid intermediates. These data suggest that growth hormone induces insensitivity to insulin in liver, muscle and fat after 120, 180 and 210 min respectively. The early effects of growth hormone on glucose metabolism seems independent of changes in the rate of lipolysis.     

Muscle sympathetic nerve activity in patients with acromegaly

Muscle sympathetic nerve activity was measured in nine acromegalic patients (age, 35 +/- 4 yr; body mass index, 28 +/- 2 kg/m2) and eight healthy subjects (age, 32 +/- 3 yr; body mass index, 25 +/- 2 kg/m2) by combining the forearm arterial-venous difference technique with the tracer method [infusion of tritiated norepinephrine (NE)]. Muscle NE release was quantified both at rest and during physiological hyperinsulinemia while maintaining euglycemia (approximately 90 mg/dL) by means of the euglycemic clamp. Arterial plasma NE was similar in the two groups at rest (197 +/- 28 and 200 +/- 27 pg/mL (-1) and slightly increased during insulin infusion. Forearm NE release was 2.33 +/- 0.55 ng x liter(-1) x min(-1) in healthy subjects and 2.67 +/- 0.61 ng x liter(-1) x min(-1) in acromegalic subjects in the basal state and increased to a similar extent during insulin infusion in both groups (3.13 +/- 0.71 and 3.32 +/- 0.75 ng x L(-1) x min(-1), P < 0.05 vs. basal), indicating a normal stimulatory effect of insulin on muscle sympathetic activity. In contrast, insulin-stimulated forearm glucose uptake was markedly lower in acromegalic patients (2.3 +/- 0.4 mg x L(-1) x min(-1)) than in control subjects (7.9 +/- 1.3 mg x L(-1) x min(-1), P < 0.001), indicating the presence of severe insulin resistance involving glucose metabolism. Our data demonstrate that patients with long-term acromegaly have normal sympathetic activity in the skeletal muscle in the basal, postabsorptive state and normal increments in NE spillover in response to the sympatho-excitatory effect of insulin. Thus, the presence of severe insulin resistance in acromegaly is not accounted for by adrenergic mechanisms.     

The influence of graded hyperglycemia with and without physiological hyperinsulinemia on forearm glucose uptake and other metabolic responses in man

We studied the influence of hyperglycemia on glucose homeostasis in man by determining the effect of graded hyperglycemia on peripheral glucose uptake and systemic metabolism in the presence of basal and increased serum insulin concentrations in 10 normal men. This was achieved by the simultaneous application of forearm and clamp techniques (euglycemic and hyperglycemic) during the combined iv infusion of somatostatin, glucagon, and insulin. While mean (+/- SE) basal serum insulin levels (14 +/- 2 microU/ml) were maintained, the elevation of fasting arterial glucose concentrations (90 +/- 1 mg/dl) to 146 +/- 1 and 202 +/- 1 mg/dl (each for 120 min) increased forearm glucose uptake (FGU) only modestly from 0.06 +/- 0.01 to 0.15 +/- 0.02 and then to 0.24 +/- 0.03 mg/100 ml forearm X min, respectively. During physiological hyperinsulinemia (47 +/- 3 microU/ml), the influence of similar graded hyperglycemia on FGU was considerably enhanced. At plasma glucose concentrations of 90 +/- 1, 139 +/- 1, and 206 +/- 1 mg/dl, FGU rose to 0.33 +/- 0.05, 0.59 +/- 0.07, and 0.83 +/- 0.12 mg/100 ml forearm X min, respectively. The glucose infusion rate required to maintain the glucose clamp with basal insulin levels was 1.08 +/- 0.20 and 2.67 +/- 0.39 mg/kg X min at glucose concentrations of 146 +/- 1 and 202 +/- 1 mg/dl, respectively. During physiological hyperinsulinemia, however, the glucose infusion rate required was 4.15 +/- 0.39, 9.45 +/- 1.05, and 12.70 +/- 0.81 mg/kg X min at glucose levels of 90 +/- 1, 139 +/- 1, and 206 +/- 1 mg/dl, respectively. Lactate concentrations rose significantly during hyperglycemia, but the rise in the presence of increased insulin concentrations (from 0.72 +/- 0.06 to 1.31 +/- 0.11 mmol/liter; P less than 0.001) considerably exceeded the increment (from 0.74 +/- 0.05 to 0.92 +/- 0.03 mmol/liter) with basal insulin levels. While both FFA and glycerol concentrations were immediately reduced by euglycemic hyperinsulinemia, the fall in FFA during hyperglycemia in the presence of basal insulin levels preceded the decrease in glycerol concentrations by 45 min. Forearm oxygen consumption did not change throughout the study.(ABSTRACT TRUNCATED AT 400 WORDS)     

Insulin-like growth factor I has a direct effect on glucose and protein metabolism, but no effect on lipid metabolism in type 1 diabetes

There is evidence of a metabolic role for IGF-I in type 1 diabetes, but it is unclear whether IGF-I acts indirectly by reducing GH secretion or has direct effects. Using stable isotopes we have investigated, on three separate occasions, the effect of a pulse of recombinant human GH, a sc injection of recombinant human IGF-I, and a placebo on glucose, lipid, and protein metabolism in subjects with type 1 diabetes during a basal insulin infusion and a hyperinsulinemic euglycemic clamp. Endogenous GH secretion was suppressed with octreotide. IGF-I reduced the hepatic glucose production rate (Ra), increased peripheral glucose uptake, and reduced protein breakdown during the basal insulin infusion (P < 0.05, P < 0.005, and P < 0.05, respectively, vs. placebo) and the hyperinsulinemic euglycemic clamp (P < 0.05, P < 0.005, and P < 0.05, respectively, vs. placebo). IGF-I had no effect on glycerol Ra, an index of lipolysis. GH increased glucose and glycerol Ra during the basal insulin infusion (P < 0.005 vs. placebo study), but the effects were no different from placebo during the clamp. In conclusion, IGF-I had a direct effect on glucose and protein metabolism, which was maintained during the hyperinsulinemic euglycemic clamp. This suggests that IGF-I acts in concert with insulin and may have an important role in maintaining glucose homeostasis and protein metabolism in type 1 diabetes.     

Impact of 2 weeks high dose growth hormone treatment on basal and insulin stimulated substrate metabolism in humans

OBJECTIVE Short-term, high dose growth hormone (GH) treatment has been advocated in many catabolic disease states. It is likely that some of the anabolic effects of GH are mediated through activation of lipolysis, but the metabolic impact of therapeutically relevant GH exposure is not known in detail. The present study was accordingly designed to assess the effects of such GH exposure on basal and insulin stimulated intermediary metabolism. DESIGN, PATIENTS AND MEASUREMENTS Six healthy young females were examined following daily injections of GH (12 IU/day) or saline for 2 weeks in a placebo controlled design. Each study consisted of a 3 hour basal period and a 2 hour hyperinsulinaemic euglycaemic clamp. RESULTS GH treatment caused (1) increased levels of IGF-I (382 ± 46 vs 294 ± 22 /μg/l, P < 0 05) and (2) increased basal values of free fatty acids (714 ±40 (GH) vs 634 ±64 (placebo) μmol/l, P<0 05), 3-hydroxybutyrate (118 3 ± 42 8 (GH) vs 57 7 ± 21 6 (placebo) μmol/l, P < 0 05), glycerol (54–3 ±8–2 (GH) vs 41–4 ±8–4 (placebo) μmol/l, P<0 05) and forearm uptake of 3-hydroxybutyrate, together with increments of plasma glucose (5 28 ±0–11 (GH) vs 4 87±0 16 (placebo) mmol/l, P<0 05). Basal forearm uptake of glucose, isotopically determined glucose turnover and serum levels of GH, insulin and C-peptide were unaltered. During the clamp GH treatment was associated with (1) a 40% decrease in the administered amount of glucose (M-value) (P<0 05) and (2) a 70% decrease in forearm glucose uptake (P<0 05). Indirect calorimetry revealed a 15% increase in resting energy expenditure (P<0 05) and a decreased basal respiratory exchange ratio (0 75 (GH) vs 0 80 (placebo), P<0 05), presumably reflecting increased lipid oxidation. CONCLUSIONS Administration of GH in a therapeutic dose for 2 weeks, despite apparently normal daytime levels of major metabolic hormones, induces significant increases in circulating lipid fuel substrates, increased energy expenditure and lipid oxidation, together with insulin resistance. Such effects should be considered when applying GH treatment schedules clinically.     

Effects of morning cortisol replacement on glucose and lipid metabolism in GH-treated subjects

OBJECTIVE: Insulin resistance is a frequent consequence of GH replacement therapy but patients on GH replacement therapy often also have replacement of other hormone deficiencies which theoretically could modify the metabolic effects of GH. In particular, cortisol replacement if given in supra physiologic doses immediately before the evaluation of insulin sensitivity could influence insulin sensitivity. The aim of this study was thus to evaluate the effect of morning cortisol replacement given prior to a euglycaemic clamp combined with infusion of [3-(3)H]glucose and indirect calorimetry on glucose and lipid metabolism. METHODS: Ten GH/ACTH-deficient adults received, in a double-blind manner, either cortisol (A) or placebo (B) before the clamp whereas five GH-deficient-ACTH-sufficient adults participated in a control (C) clamp experiment. All subjects received GH replacement therapy. RESULTS: Serum cortisol levels were significantly higher after cortisol than after placebo (324+/-156 vs 132+/-136 mmol/l; P=0.006) and similar to controls (177+/-104 mmol/l). As a measure of the biological effect of cortisol, eosinophil leukocyte counts in peripheral blood decreased (164+/-91 x 10(9)/l vs 216+/-94 x 10(9)/l; P=0.04). Cortisol replacement had no significant effect on insulin-stimulated glucose uptake (11.8+/-1.8 vs 13.2+/-3.9 micromol/kg min), either on glucose oxidation or on glucose storage. There was also no significant effect of cortisol on fasting endogenous glucose production and no effect was seen on serum free fatty acid concentrations. CONCLUSION: Administration of cortisol in the morning before a clamp cannot explain the insulin resistance seen with GH replacement therapy.     

Peripheral glucose metabolism in human hyperthyroidism

The present study was designed to determine the effect of spontaneous hyperthyroidism on the forearm muscle glucose uptake and oxidation during the postabsorptive state and after an oral glucose challenge. Ten normal subjects and 11 hyperthyroid patients were studied after an overnight fast (12-14 h) and for 3 h after ingestion of 75 g glucose. Peripheral glucose metabolism was analyzed by the forearm technique to estimate muscle exchange of substrate combined with indirect calorimetry. Increased forearm glucose uptake was observed in the hyperthyroid patients compared to that in the normal subjects (1286 +/- 212 vs. 677 +/- 88 mumol/100 mL forearm.3 h) with enhanced glucose oxidation (443 +/- 40 vs. 147 +/- 29 mumol/100 mL forearm.3 h). Nonoxidative glucose metabolism was also greater in hyperthyroid patients than in normal subjects (842 +/- 234 vs. 529 +/- 90 mumol/100 mL forearm.3 h). Basal serum FFA levels were significantly higher in hyperthyroid than in normal subjects (0.252 +/- 0.025 vs. 0.182 +/- 0.022 g/L), as were the basal lipid oxidation rates in the forearm muscles of the thyrotoxic individuals (0.290 +/- 0.066 vs. 0.088 +/- 0.016 mg/100 mL forearm.min). After glucose ingestion, serum FFA levels and lipid oxidation rates declined significantly to equivalent values in both groups of subjects, and the similar basal insulin concentrations increased to significantly higher levels in the hyperthyroid patients. In conclusion, spontaneous human hyperthyroidism increases glucose uptake by the forearm muscles in the postabsorptive state and during an oral glucose challenge, with augmented fluxes of glucose through the oxidative and nonoxidative pathways.     

Peripheral glucose metabolism in acromegaly

The present study was designed to determine the effect of chronic GH excess on forearm muscle glucose uptake and oxidation during the postabsorptive state and after an oral glucose challenge. Nine normal subjects and 10 nondiabetic acromegalic patients (5 of them with normal glucose tolerance) were studied after an overnight fast (12-14 h) and for 3 h after the ingestion of 75 g glucose. Peripheral glucose metabolism was analyzed by the forearm technique to estimate muscle exchange of substrate combined with indirect calorimetry. Decreased forearm glucose uptake was observed in the acromegalic patients compared to that in the normal subjects (380 +/- 84 vs. 709 +/- 56 mumol/100 mL forearm.3 h) with diminished nonoxidative glucose metabolism (262 +/- 81 vs. 572 +/- 53 mumol/100 mL forearm.3 h). The acromegalics with normal glucose tolerance also showed decreased forearm glucose uptake and nonoxidative glucose metabolism compared to normal subjects (271 +/- 124 vs. 709 +/- 56 and 133 +/- 110 vs. 572 +/- 53 mumol/100 mL forearm.3 h, respectively). Muscle glucose oxidation did not differ significantly in normal subjects, the entire group of acromegalic patients, and the acromegalics with normal glucose tolerance (137 +/- 18 vs. 118 +/- 22 vs. 138 +/- 34 mumol/100 mL forearm.3 h, respectively). Serum FFA levels and lipid oxidation rates were similar in the normal subjects and the acromegalic patients, and declined in a similar fashion after glucose ingestion. Insulin levels were significantly higher in acromegalic patients than in normal subjects before and after glucose loading. In conclusion, this study showed that the insulin resistance occurring in the presence of chronic GH excess is accompanied by impaired muscle glucose uptake and nonoxidative glucose metabolism, which are early derangements because they are also observed in acromegalic patients with normal glucose tolerance.     

The control on growth hormone release by free fatty acids is maintained in acromegaly

Free fatty acids (FFA) physiologically regulate GH release via a negative feedback. The aim of this study was to examine whether such feedback is preserved in acromegaly, a condition in which alterations in other regulatory mechanisms of GH release occur. Eight acromegalic patients (group 1: five women and three men, 43.0 +/- 4.2 yr old, mean +/- SE) received per os on two different days, at a 3 day-interval, in a random order, placebo or 250 mg of acipimox, an inhibitor of lipolysis analogous to nicotinic acid, at 0700 and 1100 h. In both tests GHRH (1-29 NH2), 50 microg, was administered i.v. at 1300 h. Blood samples for GH, FFA, immunoreactive insulin (IRI), and glucose were taken from 0900 to 1500 h, and the time period considered for statistical analysis was 1200-1500 h, representative of steady-state condition for FFA, IRI, and glucose. Mean plasma FFA levels (1200-1500 h) were significantly lower after acipimox than after placebo (0.05 +/- 0.01 vs. 0.17 +/- 0.01 g/L, P < 0.01). In contrast, both mean basal GH levels (1200-1300 h) and the mean GH response to GHRH (GH delta area, 1300-1500 h) were significantly higher after acipimox than after placebo (12.0 +/- 1.9 vs. 7.8 +/- 1.2 microg/L, P < 0.01; 2937 +/- 959 vs. 1154 +/- 432 microg/L x 120 min, P < 0.01). The increase in both basal GH levels and GH delta area occurred in all eight patients. Acipimox also reduced mean serum IRI (83 +/- 12 vs. 112 +/- 14 pmol/L) and blood glucose (5.1 +/- 0.1 vs. 5.7 +/- 0.1 mmol/L) levels, as compared with placebo (P < 0.03 or less). Eight acromegalic patients (group 2: six women and two men, 46.6 +/- 5.7 yr old) underwent a constant i.v. 10% lipid infusion (150 mL/h), started at 0900 h and continued until 1500 h. Mean plasma FFA levels (1200-1500 h) were significantly higher during lipid infusion than after placebo (0.27 +/- 0.01 vs. 0.16 +/- 0.01 g/L, P < 0.02); in contrast, mean basal GH levels (1200-1300 h) were reduced by lipid infusion, as compared with placebo (9.9 +/- 3.1 vs. 16.6 +/- 4.4 microg/L, P < 0.01), and the same occurred for the GH delta area after GHRH (2498 +/- 1643 vs. 4512 +/- 1988 microg/L x 120 min, P < 0.01). Serum IRI and blood glucose levels were similar after placebo and during lipid infusion. These data indicate that, in acromegaly, the acute reduction of circulating FFA levels results in increased GH release, whereas the increase in circulating FFA levels is accompanied by a reduced GH release. Taken together, these findings suggest that, in acromegaly, the control of FFA on GH release is preserved.     

Inhibition of lipolysis during acute GH exposure increases insulin sensitivity in previously untreated GH-deficient adults

OBJECTIVE: Previous studies evaluating the lipolytic effect of GH have in general been performed in subjects on chronic GH therapy. In this study we assessed the lipolytic effect of GH in previously untreated patients and examined whether the negative effect of enhanced lipolysis on glucose metabolism could be counteracted by acute antilipolysis achieved with acipimox. METHODS: Ten GH-deficient (GHD) adults participated in four experiments each, during which they received in a double-blind manner: placebo (A); GH (0.88+/-0.13 mg) (B); GH+acipimox 250 mg b.i.d. (C); and acipimox b.i.d. (no GH) (D), where GH was given the night before a 2 h euglycemic, hyperinsulinemic clamp combined with infusion of [3-(3)H]glucose and indirect calorimetry. RESULTS: GH increased basal free fatty acid (FFA) levels by 74% (P=0.0051) and insulin levels by 93% (P=0.0051). This resulted in a non-significant decrease in insulin-stimulated glucose uptakes (16.61+/-8.03 vs 12.74+/-5.50 micromol/kg per min (s.d.), P=0.07 for A vs B). The rates of insulin-stimulated glucose uptake correlated negatively with the FFA concentrations (r=-0.638, P<0.0001). However, acipimox caused a significant improvement in insulin-stimulated glucose uptake in the GH-treated patients (17.35+/-5.65 vs 12.74+/-5.50 micromol/kg per min, P=0.012 for C vs B). The acipimox-induced enhancement of insulin-stimulated glucose uptake was mainly due to an enhanced rate of glucose oxidation (8.32+/-3.00 vs 5.88+/-2.39 micromol/kg per min, P=0.07 for C vs B). The enhanced rates of glucose oxidation induced by acipimox correlated negatively with the rate of lipid oxidation in GH-treated subjects both in basal (r=-0.867, P=0.0093) and during insulin-stimulated (r=-0.927, P=0.0054) conditions. GH did not significantly impair non-oxidative glucose metabolism (6.86+/-5.22 vs 8.67+/-6.65 micromol/kg per min, P=NS for B vs A). The fasting rate of endogenous glucose production was unaffected by GH and acipimox administration (10.99+/-1.98 vs 11.73+/-2.38 micromol/kg per min, P=NS for B vs A and 11.55+/-2.7 vs 10.99+/-1.98 micromol/kg per min, P=NS for C vs B). On the other hand, acipimox alone improved glucose uptake in the untreated GHD patients (24.14+/-8.74 vs 16.61+/-8.03 micromol/kg per min, P=0.0077 for D vs A) and this was again due to enhanced fasting (7.90+/-2.68 vs 5.16+/-2.28 micromol/kg per min, P=0.01 for D vs A) and insulin-stimulated (9.78+/-3.68 vs 7.95+/-2.64 micromol/kg per min, P=0.07 for D vs A) glucose oxidation. CONCLUSION: The study of acute administration of GH to previously untreated GHD patients provides compelling evidence that (i) GH-induced insulin resistance is mainly due to induction of lipolysis by GH; and (ii) inhibition of lipolysis can prevent the deterioration of insulin sensitivity. The question remains whether GH replacement therapy should, at least at the beginning of therapy, be combined with means to prevent an excessive stimulation of lipolysis by GH.     

Expression of insulin target genes in skeletal muscle and adipose tissue in adult patients with growth hormone deficiency: effect of one year recombinant human growth hormone therapy.

Our aim was to investigate the effects of one year recombinant human growth hormone (rhGH) therapy on the regulation by insulin of gene expression in muscle and adipose tissue in adults with secondary GH deficiency (GHD). Six GHD subjects without upper-body obesity were submitted to a 3-h euglycemic hyperinsulinemic clamp before and after one year of rhGH therapy. Muscle and abdominal subcutaneous adipose tissue biopsies were taken before and at the end of each clamp. The mRNA levels of insulin receptor, p85 alpha-phosphatidylinositol-3 kinase (p85 alpha PI-3K), insulin dependent glucose transporter (Glut4), hexokinase II, glycogen synthase, lipoprotein lipase (LPL) in muscle and in adipose tissue, hormone sensitive lipase and peroxisome proliferator-activated receptor gamma (PPAR gamma) in adipose tissue were quantified by RT-competitive PCR. One year treatment with rhGH (1.25 IU/day) increased plasma IGF-I concentrations (54+/-7 vs 154+/-11 ng/ml, P<0.01) but did not affect insulin-stimulated glucose disposal rate measured during the hyperinsulinemic clamp (74+/-9 vs 85+/-5 micromol/kg free fat mass/min). Insulin significantly increased p85 alpha PI-3K, hexokinase II and Glut4 mRNA levels in muscle both before and after rhGH treatment. One year of GH therapy increased LPL mRNA levels in muscle (38+/-2 vs 70+/-7 amol/microg total RNA, P<0.05) and in adipose tissue (2490+/-260 vs 4860+/-880 amol/microg total RNA, P<0.05), but did not change the expression of the other mRNAs. We conclude from this study that GH therapy did not alter whole body insulin sensitivity and the response of gene expression to insulin in skeletal muscle of adult GHD patients, but it did increase LPL expression in muscle and adipose tissue. This result could be related to the documented beneficial effect of GH therapy on lipid metabolism.     

The GH-releasing hormone (GHRH) test in acromegaly before and after adenomectomy

The GHRH test may represent a new tool in the study of GH dynamics in acromegaly. GH responsiveness to GHRH 1-40 (50 micrograms iv) has been studied in 21 acromegalic patients. Nineteen out of 21 had active disease. Five patients were also studied 1-12 months after neurosurgery. Two apparently cured acromegalics were studied 1-2 yr after surgery. GH secretion has been evaluated in all patients by means of TRH, bromocriptine and insulin hypoglycemia tests, too. GH response to GHRH has also been performed in 14 normal subjects. In acromegaly, GH responses after GHRH (p less than 0.01 vs placebo) were variable. The GH peak ranged from 8 to 445 ng/ml in patients with active disease. Maximum GH increase after GHRH (calculated as peak/basal value ratio) was significantly reduced in acromegaly (2.9 +/- 0.5 ng/ml; mean +/- SE) in comparison to controls (34.1 +/- 10.9 ng/ml; p less than 0.01). No significant differences in GH pattern after GHRH were found between untreated and previously treated patients with active disease. A significant correlation was found between GH basal levels and GH incremental area (p less than 0.05) and between GH basal and peak levels (p less than 0.01) after GHRH. A significant increase in PRL secretion was observed in acromegalic patients after GHRH (p less than 0.01 vs placebo). No discernable variation was found in the other pituitary hormones pattern after the peptide administration. A positive correlation was observed between GH increase after GHRH and insulin hypoglycemia (p less than 0.01).(ABSTRACT TRUNCATED AT 250 WORDS)     

Glucose turnover rate and peripheral insulin sensitivity in alcoholic patients without liver damage

Glucose intolerance is frequently found in alcoholic patients and an impaired insulin response has been documented in them. To look for alternative mechanisms that could explain this intolerance, a glucose turnover using tritiated glucose and an euglycemic glucose clamp were performed to measure the glucose production rate and peripheral insulin sensitivity, respectively. Two groups of recently abstinent chronic male alcoholic patients without evidence of liver damage were studied. The glucose turnover technique showed a higher basal glucose production rate in alcoholics, compared with normal volunteers (2.83 +/- 0.29 vs. 1.84 +/- 0.22 mg/kg/min); an intravenous ethanol load significantly increased this rate. The euglycemic glucose clamp did not show peripheral insulin resistance in alcoholics, compared with controls.     

Growth hormone treatment of children with short stature increases insulin secretion but does not impair glucose disposal

Pediatricians willing to administer GH to non-GH-deficient children with short stature are concerned about the potential adverse effects of this hormone on glucose homeostasis and insulin action. This study was designed to determine the effects of GH therapy on carbohydrate metabolism in 10 prepubertal non-GH-deficient children with short stature. After 12 months of treatment with 0.3 U GH/kg BW.day, which resulted in an increase in height velocity from 4.0 +/- 0.3 (+/- SE) to 11.0 +/- 0.4 cm/yr, glucose tolerance was not impaired in these children. Not only were their fasting and postprandial plasma glucose concentrations unchanged from the pretreatment values, but basal glucose turnover did not vary; it was 0.53 +/- 0.04 before and 0.64 +/- 0.06 mmol/m2.min after GH treatment. Using the euglycemic clamp technique, the dose-response curves describing the effects of insulin on glucose disposal were comparable before and after GH treatment. There was a consistent 1.5- to 2-fold increase in plasma insulin and C-peptide concentrations during GH treatment, in both the basal and postprandial states, and after oral glucose or iv glucagon stimulation. We conclude that the GH regimen employed was remarkably effective in increasing growth velocity and devoid of detectable diabetogenic effects during a 1-yr treatment period in these non-GH-deficient children. (glucose, 1 mmol/L = 18 mg/dL; insulin, 1 pmol/L = 0.139 microU/mL; C-peptide, 1 pmol/L = 0.003 ng/ml).     

Does overnight normalization of plasma glucose by insulin infusion affect assessment of glucose metabolism in Type 2 diabetes?

AIMS: In order to perform euglycaemic clamp studies in Type 2 diabetic patients, plasma glucose must be reduced to normal levels. This can be done either (i) acutely during the clamp study using high-dose insulin infusion, or (ii) slowly overnight preceding the clamp study using a low-dose insulin infusion. We assessed whether the choice of either of these methods to obtain euglycaemia biases subsequent assessment of glucose metabolism and insulin action. METHODS: We studied seven obese Type 2 diabetic patients twice: once with (+ ON) and once without (- ON) prior overnight insulin infusion. Glucose turnover rates were quantified by adjusted primed-constant 3-3H-glucose infusions, and insulin action was assessed in 4-h euglycaemic, hyperinsulinaemic (40 mU m-2 min-1) clamp studies using labelled glucose infusates (Hot-GINF). RESULTS: Basal plasma glucose levels (mean +/- sd) were 5.5 +/- 0.5 and 10.7 +/- 2.9 mmol/l in the + ON and - ON studies, respectively, and were clamped at -5.5 mmol/l. Basal rates of glucose production (GP) were similar in the + ON and - ON studies, 83 +/- 13 vs. 85 +/- 14 mg m-2 min-1 (NS), whereas basal rates of glucose disappearance (Rd) were lower in the + ON than in the - ON study, 84 +/- 8 vs. 91 +/- 11 mg m-2 min-1 (P = 0.02). During insulin infusion in the clamp period, rates of GP, 23 +/- 11 vs. 25 +/- 10 mg m-2 min-1, as well as rates of Rd, 133 +/- 32 vs. 139 +/- 37 mg m-2 min-1, were similar in the + ON and - ON studies, respectively (NS). CONCLUSIONS: Apart from basal rates of Rd, assessment of glucose turnover rates in euglycaemic clamp studies of Type 2 diabetic patients is not dependent on the method by which plasma glucose levels are lowered.     

Effects of a physiological growth hormone pulse on substrate metabolism in insulin-dependent (type 1) diabetic subjects.

When present in inappropriate amounts GH induces substantial insulin resistance and it has furthermore been suggested that modest nocturnal surges of GH may precipitate the emergence of the dawn phenomenon. To characterize the metabolic effects of physiologically relevant, small-scale GH exposure, six type 1 diabetic subjects were studied for 5 h in the postabsorptive state after an iv pulse of either 210 micrograms GH or saline. Identical amounts of insulin were infused on both occasions to maintain a prevailing blood glucose concentration of 125 +/- 12 mg/100 ml. The GH bolus caused an increase in serum GH levels to a peak value of 22 +/- 2 micrograms/L after 10 min, a 70% increase in serum FFA (from 570 +/- 80 to 980 +/- 60 mumol/L) and a 400% increase in blood 3-hydroxybutyrate (3-OHB) (from 100 +/- 15 to 420 +/- 35 mumol/l) concentrations after 180 and 240 min respectively (P less than 0.05). Blood glycerol and forearm uptake of 3-OHB rose in parallel (P less than 0.01). Plasma glucose, isotopically measured glucose turnover and forearm glucose uptake was not affected by GH. Blood lactate concentrations increased (P less than 0.05) and nonoxidative glucose use and lipid oxidation tended to increase with GH. Energy expenditure remained unaffected. These results suggest that under everyday conditions GH acts as an important regulator of fuel fluxes in type 1 diabetic subjects, the main effect being a transient stimulation of lipolysis. Since no significant effect on glucose metabolism was recorded, we do not presently find evidence to support a primary role for small surges of GH in the pathogenesis of the dawn phenomenon.     

Modulation of basal glucose metabolism and insulin sensitivity by growth hormone and free fatty acids during short-term fasting

BACKGROUND AND AIMS: The metabolic response to fasting involves an increase in circulating levels of growth hormone (GH) and free fatty acids, and resistance to insulin's actions on glucose metabolism. Stimulation of lipolysis and insulin resistance are well-described effects of GH. The present study was designed to test the degree to which the insulin antagonistic effects of GH on glucose metabolism are mediated through stimulation of lipolysis during fasting. METHODS: Seven normal subjects were examined on three occasions during a 40-h fast with infusion of somatostatin, insulin and glucagon for the final 18 h: (expt. i) with GH replacement, (expt. ii) with GH replacement and antilipolysis with acipimox, and (expt. iii) without GH and with antilipolysis. RESULTS: Basal glucose turnover was significantly reduced by addition of acipimox (rate of disappearance (Rd) glucose (mg/kg/min): 1.91+/-0.08 (expt. i), 1.69+/-0.05 (expt. ii), 1.61+/-0.08 (expt. iii); P<0.01), whereas insulin-stimulated glucose uptake was significantly increased (glucose infusion rate (M-value) (mg/kg/min): 1.66+/-0.22 (expt. i), 2.47+/-0.10 (expt. ii), 2.00+/-0.31 (expt. iii); P<0.05). Addition of GH during inhibition of lipolysis failed to affect basal and insulin-stimulated glucose metabolism significantly. CONCLUSION: Thus, the present data provide strong evidence that the insulin antagonistic effects of GH on fasting glucose metabolism are causally linked to concomitant stimulation of lipolysis.