Effects of the combined administration of hexarelin, a synthetic peptidyl GH secretagogue, and hCRH on ACTH, cortisol and GH secretion in patients with Cushing's disease

Hexarelin (HEX) is a peptidyl GH secretagogue (GHS) which markedly stimulates GH release but, like other GHS, possesses also CNS-mediated ACTH- and cortisol-releasing activity. Interestingly, the stimulatory effect of HEX on ACTH and cortisol release is exaggerated and higher than that of hCRH in patients with Cushing's disease (CD). To further clarify the mechanisms by which HEX stimulates the activity of hypothalamo-pituitary-adrenal (HPA) axis in man, in 6 patients with CD (6 women, 38-68 yr old) and in 7 control subjects (CS, 7 women, 22-29 yr old) we studied the effects of HEX (2.0 microg/kg i.v.) and/or hCRH (2.0 microg/kg i.v.) on ACTH and cortisol (F) secretion. The GH responses to HEX alone and combined with hCRH were also studied in all subjects. Basal ACTH and F levels in CD were higher than in CS (66.3+/-5.1 vs 16.5+/-0.6 pg/ml and 217.8+/-18.5 vs 134.4+/-4.6 microg/l, respectively; p<0.02). In CS, the ACTH and F responses to HEX, evaluated as deltaAUC (mean+/-SE: 128.7+/-39.2 pg x min/ml and 328.5+/-93.2 microg x min/l, respectively) were lower, though not significantly, than those after hCRH (375.8+/-128.4 pg x min/ml and 1714.2+/-598.0 microg x min/l, respectively), though the peak ACTH and F responses to both stimuli were similar. The co-administration of HEX and hCRH had an additive effect on both ACTH (1189.6+/-237.2 pg x min/ml) and F secretion (3452.9+/-648.6 microg x min/l). In fact, the ACTH and F responses to HEX+/-hCRH were significantly higher (p<0.01) than those elicited by single stimuli. In CD, HEX induced ACTH and F responses (3603.8+/-970.7 pg x min/ml and 10955.9+/-6184.6 microg x min/l, respectively) clearly higher (p<0.002) than those in CS. The HEX-induced ACTH and F responses in CD were higher, though not significantly, than those recorded after hCRH (1432.7+/-793.5 pg x min/ml and 4832.7+/-2146.5 microg x min/l, respectively). On the other hand, the hCRH-induced ACTH and F responses in CD were similar to those in CS. In CD, the coadministration of HEX and hCRH had an additive effect on ACTH (8035.7+/-1191.1 pg x min/ml) but not on F (10985.4+/-3900.8 microg x min/l) secretion. In fact, the ACTH, but not the F response to HEX+hCRH was significantly higher (p<0.02) than that elicited by single stimuli. In conclusion, the present study demonstrates that in patients with Cushing's disease as well as in subjects control Hexarelin and hCRH have an additive effect on ACTH secretion. Considering that, at least in humans, differently from hCRH, GHS have no interaction with AVP, our present findings further agree with the hypothesis that the ACTH-releasing activity of GHS is, at least partially, independent of CRH-mediated mechanisms.     

Interaction between glucagon and hexarelin, a peptidyl GH secretagogue, on somatotroph and corticotroph secretion in humans

OBJECTIVE: Glucagon administration stimulates both somatotroph and corticotroph secretion in humans, although this happens only if glucagon is administered by the intramuscular route and not by the intravenous route. On the other hand, GH secretagogues (GHS) strongly stimulate GH and also possess ACTH-releasing activity. DESIGN AND METHODS: To clarify the mechanisms underlying the stimulatory effects of both glucagon and GHS on somatotroph and corticotroph secretion, we studied the GH, ACTH and cortisol responses to glucagon (GLU, 0.017 mg/kg i.m.) and Hexarelin, a peptidyl GHS (HEX, 2.0 microg/kg i.v.) given alone or in combination in 6 normal young volunteers (females, aged 26-32 years, body mass index 19.7-22.5 kg/m). RESULTS: GLU administration elicited a clear increase in GH (peak vs baseline, mean+/-S.E.M.: 11.6+/-3.4 vs 3. 3+/-0.7 microg/l, P<0.02), ACTH (11.6+/-3.3 vs 4.1+/-0.3 pmol/l, P<0. 02) and cortisol (613.5+/-65.6 vs 436.9+/-19.3 nmol/l, P<0.05) levels. HEX induced a marked increase in GH levels (55.7+/-19.8 vs 3. 7+/-1.9 microg/l, P<0.005) and also significant ACTH (5.7+/-1.1 vs 3. 4+/-0.6 pmol/l, P<0.01) and cortisol (400.2+/-31.4 vs 363.4+/-32.2 nmol/l, P<0.05) responses. The GH area under the curve (AUC) after HEX was clearly higher than after GLU (1637.3+/-494.0 vs 479.1+/-115. 7 microg/l/120 min, P<0.04) while HEX and GLU coadministration had a true synergistic effect on GH release (3243.8+/-687.5 microg/l/120 min, P<0.02). The ACTH and cortisol AUCs after HEX were lower (P<0. 02) than those after GLU (208.3+/-41.3 vs 426.3+/-80.9 pmol/l/120 min and 18 874.5+/-1626.1 vs 28 338.5+/-2430.7 nmol/l/120 min respectively). The combined administration of HEX and GLU had an effect which was less than additive on both ACTH (564.02+/-76.5 pmol/l/120 min) and cortisol (35 424.6+/-5548.1 nmol/l/120 min) secretion. CONCLUSIONS: These results show that the intramuscular administration of glucagon releases less GH but more ACTH and cortisol than Hexarelin. The combined administration of glucagon and Hexarelin has a true synergistic effect on somatotroph secretion but a less than additive effect on corticotroph secretion; these findings suggest that these stimuli act via different mechanisms to stimulate somatotrophs while they could have a common action on the hypothalamo-pituitary-adrenal axis.     

Alprazolam,a benzodiazepine,does not modify the ACTH and cortisol response to hCRH and AVP,but blunts the cortisol response to ACTH in humans

Alprazolam (AL), a benzodiazepine which activates gamma-amino butyrric acid (GABA)-ergic receptors, exerts a clear inhibitory effect on the activity of the hypothalamo-pituitary-adrenal (HPA) axis and is able to markedly reduce the ACTH response to metyrapone-induced inhibition of glucocorticoid feedback. It has been suggested that its inhibitory action could be regulated by CRH or AVP mediated mechanisms. However, the effect of benzodiazepines on the HPA response to CRH or AVP is contradictory. It has been shown that benzodiazepines have specific receptors on the adrenal gland but it is unclear if they mediate biological effects in humans. In order to further clarify the mechanisms underlying the inhibitory effect of benzodiazepine on HPA axis in humans, we studied the effect of AL (0.02 mg/kg po at -90 min) or placebo in 7 healthy young volunteers (7 female, age: 26-34 yr; wt: 50-58 kg, BMI 20-22 kg/m2) on: 1) the ACTH and cortisol responses to hCRH (2.0 microg/kg iv at 0 min) or AVP (0.17 U/kg im at 0 min); 2) the cortisol, aldosterone and DHEA responses to ACTH 1-24 (0.06 and 250 microg iv at 0 and 60 min, respectively). After placebo, the ACTH and cortisol responses to hCRH (peaks, mean+/-SE: 29.8+/-4.4 pg/ml and 199.3+/-19.6 microg/l) were similar to those recorded after AVP (31.7+/-6.5 pg/ml and 164.8+/-18.0 microg/l); the cortisol response to 0.06 microg ACTH (190.4+/-11.8 microg/l) was similar to that recorded after hCRH and AVP but lower (p<0.01) than that after 250 microg ACTH (260.6+/-17.4 microg/l). AL did not modify the ACTH response to both hCRH (42.5+/-7.1 pg/ml) and AVP (33.3+/-2.7 pg/ml), which even showed a trend toward increase. AL also failed to significantly modify the cortisol response to both hCRH (156.3+/-12.7 microg/l) and AVP (119.4+/-14.5 microg/l), which, on the other hand, showed a trend toward decrease. The cortisol peaks after 0.06 microg ACTH were significantly reduced (p<0.02) by AL pre-treatment (115.0+/-7.7 microg/l) which, in turn, did not modify the cortisol response to the subsequent ACTH bolus (214.7+/-16.6 microg/l). The DHEA and aldosterone responses to all the ACTH doses were not significantly modified by AL. In conclusion, these data show that the HPA response to AVP as well as to hCRH is refractory to the inhibitory effect of AL which, in turn, blunts the cortisol response to low ACTH dose. These findings suggest that both CRH- and AVP-mediated mechanisms could underlie the CNS-mediated inhibitory effect of AL on HPA axis; in the meantime, these results suggest that benzodiazepines could also act on adrenal gland by blunting the sensitivity of the fasciculata zone to ACTH.     

Corticotropin-releasing effect of hexarelin, a peptidyl GH secretagogue, in normal subjects pretreated with metyrapone or RU-486, a glucocorticoid receptor antagonist, and in patients with Addison's disease.

GH secretagogues (GHS) are peptidyl and nonpeptidyl molecules which possess strong GH-releasing activity but also stimulatory effect on hypothalamo-pituitary-adrenal axis. The ACTH and cortisol responses to Hexarelin (HEX), a peptidyl GHS, are abolished by low-dose dexamethasone pretreatment in normal subjects but are exaggerated and higher than those after hCRH in patients with pituitary ACTH-dependent Cushing's disease, in spite of their hypercortisolism. Based on the foregoing, we studied the ACTH, cortisol and GH responses to HEX (2.0 microgram/kg i.v. at 0 min) alone and after metyrapone (2 g p.o. at 23:00 h the night before) or RU-486 (400 mg p.o. at 02:00 h), a glucocorticoid receptor antagonist, in 6 normal women (NS, age 26-34 years). The endocrine responses (mean +/- SEM) to HEX alone were also studied in 8 patients with Addison's disease (AD, 6 males, 2 females, age 30-77 years; last hydrocortisone administration the day before testing). In NS, HEX stimulated basal ACTH (peak, mean +/- SEM: 26.0 +/- 7.8 vs. 10.7 +/- 2.0 pg/ml, p < 0. 05), cortisol (163.2 +/- 18.3 vs. 137.4 +/- 15.4 microgram/l, p < 0.05) and GH (72.6 +/- 23.5 vs. 3.7 +/- 1.3 microgram/l, p < 0.01) levels. Metyrapone markedly increased basal ACTH (294.4 +/- 61.6 pg/ml, p < 0.05), reduced basal cortisol (19.6 +/- 7.2 microgram/l, p < 0.05), while it did not modify GH levels. After metyrapone pretreatment the ACTH response to HEX was clearly increased (DeltaAUC: 2,857.4 +/- 901.9 vs. 367.3 +/- 274.0 pg/ml/h, p < 0.05), while the GH response was not modified. HEX did not stimulate the low cortisol levels after metyrapone pretreatment. RU-486 significantly increased basal ACTH (76.6 +/- 12.5 pg/ml, p < 0.05) and cortisol (312.7 +/- 22.2 microgram/l, p < 0.05), while it did not modify basal GH levels. RU-486 pretreatment did not modify the ACTH, cortisol and GH responses to HEX. In AD, HEX elicited a marked ACTH response (6,619.4 +/- 3,365.8 pg/ml/h; p < 0.01), which was clearly higher (p < 0.01) than that in NS after HEX alone but not significantly different from that after HEX+MET. The GH response to HEX in AD (1,325.6 +/- 284.1 microgram/l/h) was similar to that in NS (1,519.7 +/- 483.8 microgram/l/h). In conclusion, our present data demonstrate that the ACTH-releasing activity of HEX is increased in primary hypoadrenalism as well as in normal subjects after metyrapone but not after RU-486 pretreatment. These findings indicate that in normal subjects as well as in hypocortisolemic patients the ACTH-releasing activity of GHS is enhanced by the lack of negative glucocorticoid feedback.     

Effects of cortistatin-14 and somatostatin-14 on the endocrine response to hexarelin in humans

Cortistatin (CST)-14, a neuropeptide with high structural homology with somatostatine (SS)-14, binds all SS receptor subtypes but also shows activities not shared by SS. CST and SS are often co-expressed in the same neurons but are regulated by different stimuli. Moreover, CST, but not SS, also binds the GH secretagogue (GHS) receptor. We compared the effects of CST-14 and SS-14 (2.0 microg/kg/h i.v. from -30 to +90 min) on the endocrine response to hexarelin (HEX, 1.0 microg/kg i.v. at 0 min), a synthetic GHS, in 6 normal volunteers [age (mean+/-SEM): 28.7+/-2.9 yr; body mass index: 23.4+/-0.8 kg/m2]. GH, PRL, ACTH, cortisol, insulin and glucose levels were measured at each time point. CST-14 inhibited spontaneous GH secretion [delta-areas under curves (-AUC): -83.57+/-44.8 vs 2.3+/-2.7 microg/l/h, p<0.01] to the same extent of SS-14 (-186.1+/-162.9 microg/l/h, p<0.01). CST-14 as well as SS-14 also inhibited insulin secretion (p<0.05). The GH response to HEX was similarly inhibited by either CST-14 (AUC: 3814.1+/-924.2 vs 1212.9+/-379.8 microg/l/h, p<0.05) or SS-14 (720.9+/-158.6 microg/l/h, p<0.05). HEX significantly increased PRL, ACTH and cortisol levels but these responses were not modified by either CST-14 or SS-14. The effects of CST-14 and SS-14 on insulin and glucose levels were not modified by HEX. In conclusion, this study shows that CST-14 inhibits the GH response to HEX to the same extent of SS-14. Like SS-14, CST-14 also inhibits insulin secretion but both do not modify the stimulatory effects of HEX on lactotroph and corticotroph secretion. Thus, CST-14 exerts full SS-14 activity in humans.     

Tyr-Ala-Hexarelin, a synthetic octapeptide, possesses the same endocrine activities of Hexarelin and GHRP-2 in humans

Hexarelin (HEX) and GHRP-2 are two synthetic hexapeptides, superanalogs of GHRP-6, belonging to GH secretagogue (GHS) family. GHS act via specific receptors at both the pituitary and the hypothalamic level to stimulate GH release both in animals and in humans. However, GHS also possess significant PRL- and ACTH/cortisol-releasing activity. Tyr-Ala-HEX as well as Tyr-Ala-GHRP-6 are, in turn, synthetic octapeptides generally used to perform binding studies because of their easy iodination. However, their endocrine activities have never been studied in humans. To clarify the endocrine activities of Tyr-Ala-HEX, in 7 young adult volunteers we compared the effects of the maximal effective dose of HEX (2.0 microg/kg i.v.) or GHRP-2 (2.0 microg/kg i.v.) with the same one of Tyr-Ala-HEX on GH, PRL, ACTH and cortisol levels. Basal GH, PRL, ACTH and cortisol levels in all testing sessions were similar. The administration of placebo did not modify hormonal levels. HEX and GHRP-2 administration induced the well known strong GH response (Cmax, mean+/-SE: 77.3+/-6.0 and 74.1+/-12.1 microg/l; AUC, mean+/-SE: 2596.7+/-251.1 and 2480.0+/-343.6 microg*min/l). These responses were similar to that induced by Tyr-Ala-HEX (63.7+/-18.5 microg/l; 1986.6+/-622.4 microg*min/l). Moreover, HEX, GHRP-2 and Tyr-Ala-HEX had the same significant stimulatory effect on PRL (14.9+/-2.5, 12.3+/-2.0 and 10.0+/-1.5 microg/l; 497.8+/-61.8, 480.4+/-66.9 and 415.8+/-58.5 microg*min/l), ACTH (48.0+/-10.1, 51.4+/-10.6 and 44.9+/-12.2 pg/ml; 1531.6+/-235.7, 1586.7+/-277.0 and 1338.1+/-164.5 pg*min/ml) and cortisol (179.9+/-10.0, 181.2+/-14.1 and 149.7+/-20.1 microg/l; 8465.0+/-406.6, 8689.2+/-788.1 and 6295.2+/-797.0 microg*min/l). Also the mean Tmax of the endocrine responses to HEX, GHRP-2 and Tyr-Ala-HEX were similar. In conclusion, the present results demonstrate that in humans Tyr-Ala-HEX is a GH secretagogue as potent as HEX and GHRP-2, two GHRP-6 superanalogs. Tyr-Ala-HEX also shares with HEX and GHRP-2 the same PRL- ACTH- and cortisol-releasing activity.     

Impact of two or three daily subcutaneous injections of hexarelin, a synthetic growth hormone (GH) secretagogue, on 24-h GH, prolactin, adrenocorticotropin and cortisol secretion in humans

OBJECTIVE: To extend the insights on the action of GH secretagogues (GHS) on pituitary function, we studied the impact of intermittent daily s.c. administration of a peptidyl GHS, hexarelin (HEX), on 24-h GH, PRL, ACTH and cortisol release in healthy volunteers. DESIGN: We investigated the impact of two or three times daily s.c. administration of a short-acting peptidyl GHS, the hexapeptide HEX (1.5 microg/kg) on 24-h GH, PRL, ACTH and cortisol secretion (sampling every 20 min) in six normal young men. To monitor possible down-regulation, the effect of 1 microg/kg i.v. HEX at the end of each 24-h sampling period was studied. METHODS: Multi-parameter deconvolution analysis was used to quantitate pulsatile GH, PRL, ACTH and cortisol secretion and estimate the corresponding hormone half-lives. Complementary to deconvolution analysis, approximate entropy was used as a scale- and model-independent statistic to quantify the serial orderliness or pattern regularity of hormone measurements. RESULTS: Mean and integrated (24-h) serum GH concentrations were increased from baseline values to the same extent by two and three HEX injections. Both HEX schedules equally increased GH secretory burst mass (but not burst frequency), mean daily GH production rate, GH half-life and irregularity of GH release patterns. No change occurred in the secretion of IGF-I, PRL, ACTH and cortisol. Intravenous HEX at the end of each spontaneous 24-h profile induced a significant rise in GH, PRL, ACTH and cortisol. Prior HEX administration blunted the GH response, abolished that of ACTH and cortisol and did not modify the PRL increase. CONCLUSIONS: The study showed that two or three daily s.c. injections of HEX augmented 24-h GH secretion equally, amplifying selectively GH secretory pulse mass without altering lactotroph and corticotroph secretion. IGF-I levels were not modified by these 1-day HEX treatment schedules.     

Alprazolam, a benzodiazepine, blunts but does not abolish the ACTH and cortisol response to hexarelin, a GHRP, in obese patients

GH secretagogues (GHS) act on specific receptors at the pituitary and hypothalamic level and possess potent GH-releasing activity but also stimulate prolactin (PRL), ACTH and cortisol (F) secretion. However, hyperactivity of the HPA axis in obesity has been reported. The objective of this study was to clarify the endocrine activity of GHS in obesity. In nine obese patients (obese OB), 9 F, age, (34.8 +/- 3.7 y, body mass index (BMI), 35.0 +/- 2.2 kg/m2; WHR, 0.9 +/- 0.02), 14 controls (normal subjects, NS), 14 F, 30.4 +/- 0.9 y, 20.0 +/- 0.4 kg/m2), we studied the ACTH, F and GH responses to hexarelin (HEX, 2.0 microg/kg), a peptidyl GHS, alone and preceded by alprazolam (ALP, 0.02 mg/kg), and a benzodiazepine which has an inhibitory effect on corticotroph secretion. The HEX-induced ACTH response in OB was higher than that in n.s., but this difference did not attain statistical significance. In n.s. the HEX-induced ACTH response was abolished by ALP (P < 0.03) which, however, only blunted that in OB (P < 0.02). The GH response to HEX in OB was lower (P < 0.02) than that in n.s.. ALP blunted the GH response to HEX in n.s. (P < 0.03) while it did not modify that in OB. The GABAergic activation by alprazolam abolishes the ACTH response to hexarelin in normal subjects, while it only blunts that in obese subjects. Moreover, alprazolam blunts the GH response to hexarelin in normal but not in obese subjects. Thus, obese patients show partial refractoriness to the inhibitory effect of alprazolam on both corticotroph and somatotroph function.     

Endocrine activities of ghrelin, a natural growth hormone secretagogue (GHS), in humans: comparison and interactions with hexarelin, a nonnatural peptidyl GHS, and GH-releasing hormone

An endogenous ligand for the GH secretagogue-receptor (GHS-receptor) has recently been isolated, from both the rat and the human stomach, and named ghrelin. It is a 28-amino-acid peptide showing a unique structure with an n-octanoyl ester at its third serine residue, which is essential for its potent stimulatory activity on somatotroph secretion. In fact, it has been demonstrated that ghrelin specifically stimulates GH secretion from both rat pituitary cells in culture and rats in vivo. The aim of the present study was to test the GH-releasing activity of ghrelin in humans and to compare it with that of GHRH and hexarelin (HEX), a nonnatural peptidyl GHS, which possesses strong GH-releasing activity but also significantly stimulates PRL, ACTH, and cortisol secretion. To clarify the mechanisms of action underlying the GH-releasing activity of ghrelin in humans, its interaction with GHRH and HEX was also studied. Seven normal young volunteers (7 men; 24-32 yr old; body mass index, 20-24 kg/m(2)) were studied. All subjects underwent the administration of ghrelin, HEX, and GHRH-29 (1.0 microg/kg i.v. at 0 min) as well as placebo (2 mL isotonic saline i.v. at 0 min). Six subjects also underwent the combined administration of ghrelin and GHRH or HEX. Blood samples were taken every 15 min from -15 up to +180 min. GH levels were assayed at each time point in all sessions; PRL, ACTH, cortisol, and aldosterone levels were also assayed after administration of ghrelin and/or HEX. Ghrelin administration induced a prompt and marked increase in circulating GH levels (Cmax, mean +/- SEM, 92.1 +/- 16.7 microg/L; area under the curve, 1894.9 +/- 347.8 microg/L.h). The GH response to ghrelin was clearly higher (P < 0.01) than the one recorded after GHRH (26.7 +/- 8.7 microg/L; 619.6 +/- 174.4 microg/L.h) and even significantly higher (P < 0.05) than after HEX (68.4 +/- 14.7 microg/L; 1546.9 +/- 380.0 microg/L x h). Ghrelin administration also induced an increase in PRL, ACTH, and cortisol levels; these responses were higher (P < 0.05) than those elicited by HEX. A significant increase in aldosterone levels was recorded after ghrelin but not after HEX. The endocrine responses to ghrelin were not modified by the coadministration of HEX. On the other hand, the coadministration of ghrelin and GHRH had a real synergistical effect (P < 0.05) on GH secretion (133.6 +/- 22.5 microg/L; 3374.3 +/- 617.3 microg/L x h). In conclusion, ghrelin, a natural ligand of GHS-receptor, exerts a strong stimulatory effect on GH secretion in humans, releasing more GH than GHRH and even more than a nonnatural GHS such as HEX. Ghrelin, as well as HEX, also stimulates lactotroph and corticotroph secretion. Ghrelin shows no interaction with HEX, whereas it has a synergistical effect with GHRH on GH secretion. Thus, ghrelin is a new hormone playing a major role in the control of somatotroph secretion in humans, and its effects are imitated by nonnatural GHS.     

Acute cardiovascular and hormonal effects of GH and hexarelin, a synthetic GH-releasing peptide, in humans.

Reduced cardiac mass and performances are present in GH deficiency and are counteracted by rhGH replacement. GH and IGF-I possess specific myocardial receptors and have been reported able to exert an acute inotropic effect. Synthetic GH secretagogues (GHS) possess specific pituitary and hypothalamic but even myocardial receptors. In 7 male volunteers, we studied cardiac performance by radionuclide angiocardiography after iv administration of rhGH or hexarelin (HEX), a peptidyl GHS. The administration of rhGH or HEX increased circulating GH levels to the same extent (AUC: 1594.6+/-88.1 vs 1739.3+/-262.2 microg/l/min for 90 min) while aldosterone and catecholamine levels did not change; HEX, but not rhGH, significantly increased cortisol levels. Left ventricular ejection fraction (LVEF), mean blood pressure (MBP) and heart rate (HR) were unaffected by rhGH (62.4+/-2.1 vs 62.1+/-2.3%, 90.6+/-3.4 vs 92.0+/-2.5 mm Hg, 62.3+/-1.8 vs 66.7+/-2.7 bpm). HEX increased LVEF (70.7+/-3.0 vs 64.0+/-1.5%, p<0.03) without significant changes in MBP and HR (92.8+/-4.7 vs 92.4+/-3.2 mm Hg, 63.1+/-2.1 vs 67.0+/-2.9 bpm). LVEF significantly raised at 15 min, peaked at 30 min and lasted up to 60 min after HEX. These findings suggest that in man, the acute administration of Hexarelin exerts a short-lasting, positive inotropic effect. This effect seems GH-independent and might be mediated by specific GHS myocardial receptors.     

Hexarelin as a test of pituitary reserve in patients with pituitary disease

BACKGROUND: The insulin tolerance test (ITT) is the reference standard for the diagnosis of cortisol and growth hormone (GH) deficiency, but problems have occurred in small children in inexperienced hands and it is contraindicated in patients with cardiac disease and epilepsy. Hexarelin is a growth hormone-releasing peptide with GH-, ACTH/cortisol- and prolactin-releasing effects which involve both hypothalamic and direct pituitary mechanisms. We therefore investigated whether it could be used to test GH and ACTH/cortisol reserve in patients with pituitary disease. METHODS AND SUBJECTS: The changes in GH and cortisol in response to insulin-induced hypoglycaemia (intravenous human Actrapid 0.15 IU/kg) and hexarelin (2 microg/kg) in 19 patients with possible pituitary disease (5 males, mean age 39 years, range 21-70) were compared. The patients' responses during the hexarelin test were also compared to normal ranges of GH and cortisol responses established in healthy volunteers following hexarelin administration. RESULTS AND DISCUSSION: GH peak levels were significantly higher after hexarelin than after hypoglycaemia (mean +/- SEM; 67.1 +/- 16 vs. 26.9 +/- 6.8 mU/l respectively; P < 0. 001), while cortisol levels were significantly lower (420 +/- 34 vs. 605 +/- 50 nmol/l; P < 0.001). The peak responses of both hormones correlated significantly between the hexarelin and insulin-induced hypoglycaemia tests (r = 0.80, P < 0.001 for cortisol). Peak GH levels after hexarelin and ITT showed a significant positive correlation with IGF-I levels (r = 0.84 and r = 0.77, P < 0.001 for both). All patients with a subnormal GH response to hexarelin (<41.4 mU/l) had a peak GH response to ITT of <9 mU/l, and only one patient had a normal (although borderline) response to hexarelin with a subnormal GH response to the ITT. Although 17 of the 19 patients had corresponding cortisol responses to hexarelin and the ITT test (either failing or passing both), two patients had normal cortisol responses to hexarelin but subnormal responses to the ITT. A peak serum cortisol level following hypoglycaemia of >580 nmol/l is indicative of normal cortisol reserve, as established in patients undergoing surgery; only five of the normal volunteers and one of the thirteen patients with a normal ACTH/cortisol reserve on ITT had a peak cortisol >580 nmol/l in response to hexarelin. CONCLUSION: Adult patients who have a subnormal peak GH response to hexarelin are likely to be GH deficient on an insulin tolerance test. However, our data suggest that the hexarelin test is not a useful test of ACTH/cortisol reserve. The hexarelin test could be a useful first/screening test to diagnose adult GH deficiency, particularly in patients in whom an insulin tolerance test is contraindicated or who are already ACTH deficient and in whom the GH reserve alone is of interest.     

Glucagon administration elicits blunted GH but exaggerated ACTH response in obesity

Reduction in both spontaneous and stimulated GH secretion in obesity has been clearly demonstrated. Mild hyperactivity of hypothalamus-pituitary-adrenal (HPA) axis has been also reported. Glucagon, at least after im administration, induces clear increase in either GH or ACTH and F levels but its effect on somatotroph and corticotroph secretion in obesity has never been studied. In 7 patients with abdominal obesity (OB, aged 24-42 yr, BMI: 29.1-43.9 kg/m2, waist/hip ratio [WHR]: 0.86-1.00) we studied the GH, ACTH and F responses to the im administration of glucagon (0.017 mg/kg at 0 min). The results in OB were compared with those in a group of 6 age-matched controls normal subjects (Ns aged 26-32 yr, BMI 19.7-22.5 kg/m2). In Ns glucagon administration induced clear increase in GH (peak vs baseline, mean+/-SE: 11.6+/-3.4 vs 3.3+/-0.7 microg/l, p<0.02), and ACTH (52.9+/-15.2 vs 19.0+/-1.5 pg/ml, p<0.02) levels which peaked at +150 and +165 min, respectively. Increase in F levels (222.3+/-23.8 vs 158.3+/-7.0 ng/ml, p<0.05) was also recorded but peaked at +180 min. In OB glucagon administration induced GH response (7.4+/-2.3 vs 0.8+/-0.6 microg/l) lower (p<0.05) than that recorded in Ns; when the GH responses were evaluated by co-variance analysis, a significant difference between the 2 groups was recorded in term of peaks but not of AUCs. On the other hand, the ACTH response to glucagon in OB was higher than that in Ns (11452.6+/-2447.7 vs 4892.2+/-719.4 pg/ml x min, p<0.05). The F response to glucagon in OB and Ns was, however, similar (24057.9+/-4109.1 vs 29835.9+/-1566.0 ng/ml x min). In conclusion, this study demonstrates that in obese patients the im administration of glucagon elicits blunted GH response but exaggerated ACTH increase which is uncoupled with the adrenal response. These findings agree with the existence of concomitant GH insufficiency and altered corticotroph function in obesity.     

The negative GH auto-feedback in childhood: effects of rhGH and/or GHRH on the somatotroph response to GHRH or hexarelin, a peptidyl GH secretagogue, in children

Aim of the present study was to further clarify the negative GH auto-feedback mechanisms in childhood. To this goal we studied the effects of rhGH and/or GHRH administration on the GH response to GHRH or hexarelin (HEX), a peptidyl GH secretagogue, in normal short children. In 34 prepubertal children (12 girls and 22 boys, age 8.2- 14.2 yr) with normal short stature (normal height velocity and IGF-I levels) the following tests were performed: group A (no.=11): GHRH (GHRH 1 - 29, Geref, Serono; 1 microg/kg iv at 150 min) preceded by saline or GHRH at 0 min; group B (no.=6): GHRH preceded by saline or rhGH (0.005 IU/kg iv at 0 min); group C (no.=6): GHRH preceded by rhGH alone or combined with GHRH; group D (no.=6): HEX (2 microg/kg iv at 150 min) alone or preceded by rhGH. In group A, the GH response to GHRH was not modified by pre-treatment with GHRH (GH peak, mean+/-SEM: 16.7+/-2.9 vs 15.1+/-2.3 microg/l, respectively). In group B, the GH response to GHRH was clearly inhibited by rhGH (8.7+/-2.3 vs 38.8+/-4.5 microg/l, p<0.001); the GH rise after rhGH in group B overlapped with that after GHRH in group A. In group C, the GH response to GHRH after pre-treatment with rhGH (13.2+/-4.0 microg/l) was similar to that in group B and was not significantly modified by pre-treatment with rhGH+ GHRH (6.9+/-2.7 microg/l); the GH rise after rhGH+GHRH was higher (p<0.05) than that after rhGH alone. In group D, the GH response to HEX was significantly blunted by pre-treatment with rhGH (34.1+/-11.7 vs 51.2+/-17.9 microg/l, p<0.05). Our results demonstrate that in childhood the somatotroph response to GHRH is preserved after GHRH while it is inhibited after rhGH administration, which is also able to blunt the GH response to HEX. Thus, the somatostatin-mediated negative GH auto-feedback is already operative in childhood; the reason why the GHRH- induced GH rise is not inhibited by GHRH pre-treatment is unexplained.     

RECOVERY FROM GLUCOCORTICOID INHIBITION OF THE RESPONSES TO CORTICOTROPHIN-RELEASING HORMONE

We have characterized the recovery of the hypothalamic-pituitary-adrenal (HPA) axis from inhibition by short-term prednisolone administration. Prednisolone was given in a dosage averaging 25 mg at 12 h intervals orally for up to 2 weeks to adult volunteers. Human corticotrophin releasing hormone (hCRH) tests were performed at 0901 h using a bolus injection of 1 microgram/kg before and 24-48 h after discontinuing the prednisolone. In the initial control study, hCRH stimulated a two-fold rise in plasma ACTH and a 30% rise in plasma cortisol within 30 min (ACTH rose from 18.5 +/- 4.5, SEM, pg/ml to 36.5 +/- 12.6 pg/ml and cortisol from 415 +/- 58 to 531 +/- 69 nmol/l in response to hCRH. One dose of prednisolone had no effect on the ACTH or cortisol response to hCRH administered 24 h later. Twenty-four hours after discontinuing a 1 week course of prednisolone, baseline plasma ACTH (3.9 +/- 0.6 pg/ml) and cortisol (146 +/- 17 nmol/l) were markedly suppressed, as was the cortisol response to hCRH (peak 198 +/- 22). However, the plasma ACTH response to hCRH was not significantly suppressed. Forty-eight hours after discontinuing prednisolone, the recovery of ACTH secretion was complete (baseline 10.9 +/- 4.2, peak 36.4 +/- 14.8 pg/ml), but the cortisol response to hCRH was still depressed (peak 294 +/- 66 nmol/l). Recovery from a 2 week course of prednisolone had similar characteristics except plasma cortisol was depressed more profoundly. Plasma dehydroepiandrosterone (DHA) during hCRH tests and dehydroepiandrosterone sulphate (DHAS) paralleled plasma cortisol.(ABSTRACT TRUNCATED AT 250 WORDS)     

GHRP-6 is able to stimulate cortisol and ACTH release in patients with Cushing's disease: comparison with DDAVP

It has been shown that hexarelin stimulates ACTH and cortisol secretion in patients with Cushing's disease. The ACTH release induced by this peptide is 7-fold greater than that obtained by hCRH. The mechanism of action of hexarelin on the hypothalamic-pituitary-adrenal axis has not been fully elucidated. Although controversial, there is evidence that it might be mediated by arginine vasopressin (AVP). The aim of this study was to evaluate the ACTH and cortisol releasing effects of GHRP-6 in patients with Cushing's disease and to compare them with those obtained with DDAVP administration. We studied 10 patients with Cushing's disease (8 female, 2 male; age: 36.7 +/- 4.2 yr), 9 with microadenomas, who were submitted to both GHRP-6 (2 microg/kg iv) and DDAVP (10 micro g i.v.) in bolus administration on 2 separate occasions. ACTH was measured by immunochemiluminometric assay and cortisol by radioimmunoassay. The sensitivities of the assays are 0.2 pmol/l for ACTH, and 11 nmol/l for cortisol. GHRP-6 was able to increase significantly both ACTH (pmol/l, mean +/- SE; basal: 15.5 +/- 1.7 vs peak: 45.1 +/- 9.3) and cortisol values (nmol/l, basal: 583.0 +/- 90.8 vs peak: 1013.4 +/- 194.6). ACTH AUC (pmol/l min(-1)) and cortisol AUC (nmol/l min(-1)) values were 1235.4 and 20577.2, respectively. After DDAVP administration there was a significant increase in ACTH (basal: 13.0 +/- 1.4 vs peak: 50.5 +/- 16.2) and cortisol levels (basal: 572.5 +/- 112.7 vs peak: 860.5 +/- 102.8. AUC values for ACTH and cortisol were 1627.6 +/- 639.8 and 18364.7 +/- 5661.4, respectively. ACTH and cortisol responses to GHRP-6 and DDAVP did not differ significantly (peak: 45.1 +/- 9.3 vs 50.5 +/- 16.2; AUC: 1235.4 +/- 424.8 vs 1627.6 +/- 639.8). There was a significant positive correlation between peak cortisol values after GHRP-6 and DDAVP administration (r = 0.87, p = 0.001). Our results show that GHRP-6 is able to stimulate ACTH and cortisol release in patients with Cushing's disease. These responses are similar to those obtained after DDAVP injection. These findings could suggest the hypothesis that both peptides act by similar mechanisms, either at hypothalamic or pituitary level.     

Endocrine responses to ghrelin in adult patients with isolated childhood-onset growth hormone deficiency

OBJECTIVE: Ghrelin, a 28 amino acid acylated peptide, is a natural ligand of the GH secretagogues (GHS) receptor (GHS-R), which is specific for synthetic GHS. Similar to synthetic GHS, ghrelin strongly stimulates GH secretion but also displays significant stimulatory effects on lactotroph and corticotroph secretion. It has been hypothesized that isolated GH deficiency (GHD) could reflect hypothalamic impairment that would theoretically involve defect in ghrelin activity. PATIENTS: In the present study, we verified the effects of ghrelin (1 microg/kg i.v.) on GH, PRL, ACTH and cortisol levels in adult patients with isolated severe GHD [five males and one female, age (mean +/- SEM) 24.7 +/- 2.6 years, BMI 25.7 +/- 2.7 kg/m2]. In all patients, the GH response to insulin-induced hypoglycaemia (ITT, 0.1 IU regular insulin i.v.) and GH releasing hormone (GHRH) (1 microg/kg i.v.) + arginine (ARG, 0.5 g/kg i.v.) was also studied. The hormonal responses in GHD were compared with those in age-matched normal subjects (NS, seven males, age 28.6 +/- 2.9 years, BMI 22.1 +/- 0.8 kg/m2). RESULTS: IGF-I levels in GHD were markedly lower than in NS (69.8 +/- 11.3 vs. 167.9 +/- 19.2 microg/l, P < 0.003). Ghrelin administration induced significant increase in GH, PRL, ACTH and cortisol levels in all GHD. In GHD, the GH response to ghrelin was higher (P < 0.05) than that to GHRH + ARG, which, in turn, was higher (P < 0.05) than that to ITT (9.2 +/- 4.1 vs. 5.3 +/- 1.7 vs. 1.4 +/- 0.4 microg/l). These GH (1 microg/l = 2 mU/l) responses in GHD were markedly lower (P < 0.0001) than those in NS (ghrelin vs. GHRH + ARG vs. ITT 92.1 +/- 16.7 vs. 65.3 +/- 8.9 vs. 17.7 +/- 3.5 microg/l). In GHD, the highest individual peak GH response to ghrelin was markedly lower than the lowest peak GH response in NS (28.5 vs. 42.9 microg/l). GHD and NS showed overlapping PRL (1 microg/l = 32 mU/l) (10.0 +/- 1.4 vs. 14.9 +/- 2.2 microg/l), ACTH (22.3 +/- 5.3 vs. 18.7 +/- 4.6 pmol/l) and cortisol responses (598.1 +/- 52.4 vs. 486.9 +/- 38.9 nmol/l). CONCLUSIONS: This study shows that ghrelin is one of the most powerful provocative stimuli of GH secretion, even in those patients with isolated severe GHD. In this condition, however, the somatotroph response is markedly reduced while the lactotroph and corticotroph responsiveness to ghrelin is fully preserved, indicating that this endocrine activity is fully independent of mechanisms underlying the GH-releasing effect. These results do not support the hypothesis that ghrelin deficiency is a major cause of isolated GH deficiency but suggest that ghrelin might represent a reliable provocative test to evaluate the maximal GH secretory capacity provided that appropriate cut-off limits are assumed.     

The growth hormone secretagogue hexarelin stimulates the hypothalamo-pituitary-adrenal axis via arginine vasopressin.

GH secretagogues (GHSs) act via specific receptors in the hypothalamus and the pituitary gland to release GH. GHSs also stimulate the hypothalamo-pituitary-adrenal (HPA) axis via central mechanisms probably involving CRH or arginine vasopressin (AVP). We studied the effects of hexarelin, CRH, and desmopressin, an AVP analog, on the stimulation of the HPA axis in 15 healthy young male volunteers. Circulating ACTH, cortisol, GH and PRL concentrations were measured for 2 h after the injection of hexarelin, CRH, or desmopressin alone and the combination of hexarelin plus CRH or hexarelin plus desmopressin. Symptoms during the tests were assessed by visual analog scales. Hexarelin significantly increased ACTH and cortisol release (area under the curve, 3,444+/-696 ng/L x 125 min and 45,844+/-2,925 nmol/L x 125 min, respectively), and this effect was augmented by the addition of CRH in a dose that on its own produces maximal stimulation (6,580+/-1,572 ng/mL x 125 min and 63,170+/-2,616 nmol/L x 125 min; P = 0.01 and 0.001, respectively), but was not influenced by the addition of desmopressin (3,540+/-852 ng/mL x 125 min and 35,319+/-3,252 nmol/L x 125 min; not significant). CRH on its own caused similar or slightly higher ACTH and cortisol release than hexarelin alone. Desmopressin given alone elicited a rapid rise in circulating ACTH and cortisol, but its effects were less than those of any other treatment and were not augmented by hexarelin. Hexarelin also caused significant GH and PRL release, but these effects were not influenced by the coadministration of CRH or desmopressin. Visual analog scales showed an acute small increment in appetite with hexarelin. Our data suggest that the effect of GHSs on the HPA axis involve at least in part the stimulation of AVP release. In summary, we have shown that in healthy male volunteers, the effect of hexarelin on the HPA axis does not involve CRH, but may occur through the stimulation of AVP release.     

Effects of estrogen and recombinant human insulin-like growth factor-I on ghrelin secretion in severe undernutrition

Ghrelin is a nutritionally regulated gut peptide that increases with fasting and chronic undernutrition and decreases with food intake. Sex steroid levels change in chronic undernutrition and might signal changes in ghrelin. At the same time, chronic undernutrition is characterized by low IGF-I that might also influence ghrelin, either directly or through changes in the GH axis. Little is known regarding sex steroid regulation of ghrelin and the effects of IGF-I on ghrelin in severe undernutrition. We investigated the effects of sex steroids and IGF-I on ghrelin in 78 female subjects with anorexia nervosa simultaneously randomized to receive estrogen (Ovcon 35, 35 microg ethinyl estradiol, and 0.4 mg norethindrone) as well as recombinant human (rh)IGF-I (30 microg/kg sc twice a day) in a two-by-two factorial model, in which the individual effects of estrogen (E) and rhIGF-I on ghrelin could be determined. Subjects were 24.9 +/- 0.7 (mean +/- sem) yr of age and had low weight (body mass index, 16.7 +/- 0.2 kg/m(2)). At baseline, ghrelin was inversely correlated with body mass index (r = -0.39, P = 0.0005) and IGF-I (r = -0.30, P = 0.01). IGF-I increased significantly more in subjects receiving rhIGF-I alone (Delta 23.0 +/- 5.8 nmol/liter) and rhIGF-I and E (Delta 34.9 +/- 6.3 nmol/liter) compared with subjects receiving E alone (Delta -3.2 +/- 1.9 nmol/liter) or control (C; rhIGF-I placebo and no E) (Delta 0.4 +/- 2.0 nmol/liter) (overall P < 0.0001 by multivariate analysis of variance, P < 0.0001 for rhIGF-I vs. C, P < 0.0001 for rhIGF-I and E vs. C). Ghrelin increased significantly more over 6 months in response to E alone (Delta 150 +/- 86 pg/ml), rhIGF-I alone (Delta 198 +/- 116 pg/ml), and the combination (E and rhIGF-I) (Delta 441 +/- 214 pg/ml) compared with C (Delta -39 +/- 48 pg/ml) (overall P = 0.02 by multivariate analysis of variance, P = 0.01 for E vs. C, P = 0.04 for rhIGF-I vs. C, and P = 0.001 for rhIGF-I and E vs. C). Weight, caloric intake, and morning GH levels did not change significantly between the groups, but the change in ghrelin was inversely related to the change in GH among all subjects (r = -0.27, P = 0.03).Our data demonstrate that, in a model of severe undernutrition, rhIGF-I and E individually increase ghrelin levels. The mechanisms of these effects are unknown and may relate to direct effects on ghrelin or changes in GH. Further studies are needed to determine the mechanisms by which rhIGF-I and E increase ghrelin in human physiology.     

Obese patients with obstructive sleep apnoea syndrome show a peculiar alteration of the corticotroph but not of the thyrotroph and lactotroph function

OBJECTIVE: Obstructive sleep apnoea syndrome (OSAS) is strongly associated with obesity (OB) and is characterized by several changes in endocrine functions, e.g. GH/IGF-I axis, adrenal and thyroid activity. It is still unclear whether these alterations simply reflect overweight or include peculiar hypoxia-induced hormonal alterations. Hormonal evaluations have been generally performed in basal conditions but we have recently reported that OSAS is characterized by a more severe reduction of the GH releasable pool in comparison to simple obesity. We aimed to extend our evaluation of anterior pituitary function to corticotroph, thyrotroph and lactotroph secretion under dynamic testing in OSAS in comparison with simply obese and normal subjects. SUBJECTS AND METHODS: In 15 male patients with OSAS [age, mean +/- SEM 43.5 +/- 1.6 years; body mass index (BMI) 39.2 +/- 3.1 kg/m2; apnoea/hypopnoea index, (AHI) 53.4 +/- 8.7], 15 male patients with simple obesity (OB, age 39.7 +/- 1.2 years; BMI 41.2 +/- 2.0 kg/m2; AHI 3.1 +/- 1.2 events/h of sleep) and in 15 normal lean male subjects (NS, age 38.2 +/- 1.4 years; BMI 21.2 +/- 0.8 kg/m2; AHI 1.9 +/- 0.8 events/h of sleep) we evaluated: (a) the ACTH and cortisol responses to CRH [2 microg/kg intravenously (i.v.)] and basal 24 h UFC levels; (b) the TSH and PRL responses to TRH (5 microg/kg iv) as well as FT3 and FT4 levels. RESULTS: Twenty-four-hour UFC levels in OSAS and OB were similar and within the normal range. Basal ACTH and cortisol levels were similar in all groups. However, the ACTH response to CRH in OSAS (Deltapeak: 30.3 +/- 3.8 pmol/l; DeltaAUC: 682.8 +/- 128.4 pmol*h/l) was markedly higher (P < 0.001) than in OB (Deltapeak: 9.3 +/- 1.4 pmol/l; DeltaAUC 471.5 +/- 97.3 pmol*h/l), which, in turn, was higher (P < 0.05) than in NS (Deltapeak: 3.3 +/- 0.9 pmol/l; DeltaAUC 94.7 +/- 76.7 pmol*h/l). On the other hand, the cortisol response to CRH was not significantly different in the three groups. Basal FT3 and FT4 levels as well as the TSH response to TRH were similar in all groups. Similarly, both basal PRL levels and the PRL response to TRH were similar in the three groups. CONCLUSIONS: With respect to patients with simple abdominal obesity, obese patients with OSAS show a more remarkable enhancement of the ACTH response to CRH but a preserved TSH and PRL responsiveness to TRH. These findings indicate the existence of a peculiarly exaggerated ACTH hyper-responsiveness to CRH that would reflect hypoxia- and/or sleep-induced alterations of the neural control of corticotroph function; this further alteration is coupled to the previously described, peculiar reduction of somatotroph function.     

Radionuclide angiocardiographic evaluation of the cardiovascular effects of recombinant human IGF-I in normal adults

OBJECTIVE: IGF-I possesses specific myocardial receptors and is able to promote cardiac remodelling and even inotropic effects in both humans and other animals. In fact, reduced cardiac mass and performance are present in GH deficiency and these alterations are counteracted by recombinant human (rh) GH replacement, restoring IGF-I levels. Recently, the acute administration of 60 microg/kg rhIGF-I has also been reported to be able to improve cardiac performance evaluated by echocardiography or impedance cardiography in normal subjects. The aim of our study was to verify the effects of a subcutaneous low dose of rhIGF-I (20 microg/kg) on cardiac performance in humans. METHODS: In six healthy male adults (mean+/-S. e.m.: 35.7+/-4.3 years of age), the effects of rhIGF-I on left ventricular function evaluated by radionuclide angiocardiography and on circulating IGF-I, GH, insulin, glucose and catecholamines levels were studied. RESULTS: Administration of rhIGF-I increased circulating IGF-I (peak at +150 min vs baseline: 330.2+/- 9.6 vs 199. 7+/-8.7 microg/l, P<0.03) to levels which persisted similarly up to +180min. Neither GH nor catecholamine levels were modified by rhIGF-I administration, while insulin and glucose levels showed a slight but significant decrease. Basal left ventricular ejection fraction (61.8+/-2.0%) significantly increased at +180 min after rhIGF-I (65.3+/-2.7%, P<0.03). No change was recorded in mean blood pressure while a non-significant trend towards a reduction of heart rate was present by +120 min. CONCLUSIONS: These findings indicate that even subcutaneous administration of a low dose of rhIGF-I has acute inotropic effects as evaluated by radionuclide angiocardiography in healthy adults.