Acute administration of corticoids: a new and peculiar stimulus of growth hormone secretion in man.

It is widely accepted that chronic administration of corticoids in man inhibits the GH response to all of the stimuli tested so far. To study the action of corticoids administered acutely, several dexamethasone challenge tests were performed, after which GH levels were measured for 7 h. In eight volunteers, administration of 4 mg dexamethasone (Dex), iv, induced a clear-cut GH release compared with saline administration. The secretion followed an unusual pattern; basal GH levels (1.5 +/- 0.1 micrograms/L) started rising 2 h after Dex injection, reaching a peak of 17.5 +/- 4.4 micrograms/L after 3 or 3.5 h. Peak levels were maintained until 5 h post-Dex and decreased thereafter. Similar data were obtained when Dex was administered to five volunteers at the dose of 8 mg, orally, with a 30-min delay of the GH peak (19.6 +/- 7.9 micrograms/L). To study whether there was a cholinergic input responsible for the Dex action, another group of eight volunteers underwent three Dex tests (4 mg, iv) on three occasions, followed 90 min later by the administration of placebo (control), atropine (0.5 mg, iv), or pyridostigmine (120 mg, orally). The Dex-induced GH peak (20.8 +/- 5.2 micrograms/L) was not significantly increased by pyridostigmine (cholinergic agonist) treatment (24.2 +/- 4.0 micrograms/L). The blockade of muscarinic receptors by atropine induced a delay in the Dex-induced secretory peak, which appeared at 5 h. However, the Dex-atropine GH peak (14.9 +/- 4.1 micrograms/L) was not different from the Dex-placebo one. In conclusion, Dex alone is able to induce a clear-cut GH secretion in man. The stimulus followed a peculiar time pattern, with peaks levels attained 3 h after either iv or oral administration.

Effect of enhancement of endogenous cholinergic tone with pyridostigmine on the dose-response relationships of growth hormone (GH)-releasing hormone-induced GH secretion in normal subjects.

It is well known that GH responses to GH-releasing hormone (GHRH) show marked interindividual variations in normal subjects, which have been attributed to a variable somatostatinergic tone. Recently, it has been shown that enhancement of cholinergic tone with the acetylcholinesterase inhibitor pyridostigmine (PD), which presumably acts by inhibiting somatostatin release, stimulates basal GH secretion and GH responses to a maximal dose of GHRH. In this study we have investigated the effects of PD on the dose-response relationships of GHRH-induced GH secretion in normal subjects. Our data showed that PD (120 mg, orally, at-60 min) induced a clear-cut increase in basal GH levels, significantly different from that after saline treatment, at 15, 30, 45, 60, 90, and 120 min. Moreover, PD administration markedly potentiated GH responses to GHRH at doses of 500, 100, 25, 10, and 3 micrograms/subject, as assessed by either area under the curve or maximal peak GH levels. In fact, GH responses to pyridostigmine plus 3 micrograms GHRH were similar to those to the administration of 500 and 100 micrograms GHRH alone. Our findings of marked increases in GH response to GHRH after pyridostigmine administration show that with enhancement of cholinergic tone, the dose of GHRH needed to induce a similar increase in GH is reduced 30 times.

Corticosteroid-induced growth hormone secretion in normal and obese subjects.

OBJECTIVE: In normal subjects, corticosteroids stimulate growth hormone (GH) secretion at 3 hours. Obesity is associated with blunted GH secretion. In order to clarify both the deranged mechanism of GH secretion in obesity and the corticosteroid mechanism of action we have assessed in normal and obese subjects the effects of dexamethasone, pyridostigmine (a drug capable of suppressing somatostatin release) and GHRH. We also compared in normal subjects the stimulatory effect of three different corticosteroids on plasma GH levels. DESIGN: In both normal and obese subjects the following tests were carried out: placebo; dexamethasone alone (4 mg i.v. at 0 minutes); and dexamethasone plus pyridostigmine (120 mg p.o. at 60 minutes). In normal subjects we also studied the effects of hydrocortisone (100 mg i.v. at 0 minutes) and deflazacort (a corticosteroid that does not cross the blood-brain barrier) (60 mg i.v. at 0 minutes). In obese subjects we also assessed the effect of dexamethasone plus GHRH (100 micrograms i.v. at 150 minutes) on plasma GH levels. PATIENTS: Ten normal subjects and 22 obese subjects were studied. Normal controls were within 10% of their ideal body weight. Obese subjects had a body mass index of 37.1 +/- 1.1 (mean +/- SEM). MEASUREMENTS: Plasma GH levels were measured by radioimmunoassay. RESULTS: Dexamethasone-induced GH secretion in normal subjects (28.6 +/- 7.8 millimicron/l, P less than 0.05). Corticosteroids did not alter GH levels in obese subjects. Pretreatment with pyridostigmine increased dexamethasone-induced GH release in normal subjects (40.8 +/- 6.8 millimicron/l) but this did not achieve statistical significance. Dexamethasone plus pyridostigmine did not alter GH levels in obese subjects (8.0 +/- 1.6 mU/l). In some subjects, dexamethasone pretreatment potentiated GHRH-stimulated GH secretion, while in half the subjects the basal GH levels were not altered. In control subjects, hydrocortisone and deflazacort caused GH release similar to dexamethasone. CONCLUSIONS: Corticosteroids are a new and selective stimulus of GH secretion. They do not cause GH release in obese subjects. Their relative independence from cholinergic control suggest that they act by reducing somatostatin secretion.

Steroids and neuroendocrine function in anorexia nervosa.

Anorexia nervosa is a primarily psychiatric syndrome of self-induced weight loss due to an intense fear of becoming obese. Numerous endocrine abnormalities occur in anorexia nervosa patients, and in many respects these alterations reflects the endocrinology of reduced energy intake. However, the basic mechanisms of those alterations are far from being understood. In an attempt to understand the disrupted mechanisms of the hypogonadotropic hypogonadism of the anorectic state, we studied 10 anorectic women in the acute phase of their illness; all met the DSM III criteria. On each patient, two tests were performed with either saline as control or infusion of the opioid antagonist naloxone, and both LH and FSH levels were measured. Four mg of naloxone as bolus was used, followed by a naloxone infusion of 2 mg/h for 4 h. Compared with the pattern of normal women, naloxone did not increase in the anorectic patients either LH or FSH levels nor pulsatility. This result suggests that endogenous opioid peptides are not implicated in the low gonadotropic situation of anorexia nervosa. An alternative explanation could be that the low estrogenic "milieu" of these patients could mask the opioid action. To test this second possibility, another group of 7 anorectic women after partial weight recovery were challenged with estrogen administration. Compared with the pattern of normal women volunteers, all the anorectic patients but one presented an abnormal response in both LH and FSH levels after estrogen administration. In fact, the negative feedback and the delayed positive feedback of LH after estrogen were absent in these patients. Interestingly enough, the only patient with near-normal LH response to estrogen was considered fully recovered by the Psychiatric Unit. Several alterations in the hypothalamic-pituitary-adrenal axis has been reported in anorexia nervosa. Seven anorectic patients and 7 aged-matched women were challenged by ACTH 1-24, 250 micrograms (i.v.) and the ratio of increments in adrenal steroid products to precursors monitored. ACTH-induced increments in cortisol with respect to increments in 17-OH-progesterone was similar in anorectics and controls. On the contrary, the ratio of increments of androstenedione with respect to increments in 17-OH-progesterone were greater in anorexia nervosa than controls. These results suggest that in anorexia nervosa the 11-beta-21-alpha-hydroxylase system is normal but a deficient 17-20 desmolase system is present. Finally, the altered pattern of GH secretion in anorexia was studied using GHRH (1 microgram/kg) as stimulus of pituitary GH secretion.(ABSTRACT TRUNCATED AT 400 WORDS)

Influence of hyperthyroidism on growth hormone secretion.

OBJECTIVE: Hyperthyroidism is associated with altered GH secretion. Whether this is due to changes of somatotroph responsiveness or reflects an alteration in negative feedback signals at the hypothalamic level is unknown. We therefore performed a series of studies to shed some light onto this issue. DESIGN: Study 1: GHRH (1 microgram/kg b.w.) was injected i.v. in 38 hyperthyroid patients and in 30 normal subjects; in 11 of the patients the GHRH test was repeated following methimazole-induced remission of hyperthyroidism. Study 2: hGH (2 U i.v.) or saline were administered 3 hours prior to GHRH; six hyperthyroid patients and six normal subjects were studied. Study 3: ten normal subjects and ten hyperthyroid patients were given 75 g oral glucose or water 30 minutes before GHRH. Study 4: 11 normal subjects and eight hyperthyroid patients were studied. TRH or vehicle were dissolved in 250 ml of saline solution and infused at a rate of 400 micrograms/h for 150 minutes. Thirty minutes after the beginning of the infusions, L-arginine (30 g infused over 45 min i.v.) was administered. PATIENTS: Hyperthyroid patients were compared to normal subjects. MEASUREMENTS: Growth hormone was measured by RIA at 15-minute intervals. RESULTS: GH responses to GHRH were subnormal in hyperthyroid patients. Following antithyroid drug treatment with methimazole, GH responses to GHRH increased in these patients in comparison to pretreatment values. Serum IGF-I levels, which were elevated before treatment, decreased after methimazole administration. Exogenous GH administration induced a clear decrease of GH responses to GHRH in both control and hyperthyroid subjects. On the other hand, oral glucose load decreased the GH responses to GHRH in normal but not in hyperthyroid subjects. TRH administration did not modify the GH responses to arginine in either normal subjects or hyperthyroid patients. CONCLUSIONS: Hyperthyroidism is associated with increased serum IGF-I levels and marked alterations in the neuroregulation of GH secretion. These changes involve decreased GH responsiveness to GHRH at the pituitary level and, at the hypothalamic level, a lack of suppressive effect of an oral glucose load. The normal inhibitory effect of exogenous GH administration but not of an oral glucose load in hyperthyroid patients suggests that these two feedback signals act through different mechanisms. The lack of effect of a TRH infusion on GH responses to L-arginine in normal and hyperthyroid patients makes an inhibitory role for TRH in GH secretion unlikely, at least in Caucasian subjects.

Dual and selective actions of glucocorticoids upon basal and stimulated growth hormone release in man.

In humans, corticoids suppress growth and growth hormone (GH) secretion elicited by a variety of stimuli, while in the rat they potentiate both in vivo and in vitro GH release. To further study this problem, growth-hormone-releasing hormone (GHRH) tests were performed in 6 nonobese Cushing's syndrome patients and 6 controls. The normal GHRH-induced GH secretion was completely abolished in the Cushing's syndrome group. To study the action of shorter corticoid exposures, 34 volunteers were subjected to four tests each: placebo treatment (control); dexamethasone (Dex) administration 4 mg i.v., 3 h before; Dex 8 mg p.o., 12 h before, and Dex 22 mg p.o. over the 2 days before the pituitary challenge that was always administered at 0 min (12.00 h). In the first test (n = 9), GHRH (1 microgram/kg i.v.) induced a GH peak of 14.5 +/- 3.8 ng/ml (control) that was potentiated by Dex 4 mg i.v. administered 3 h before (26.4 +/- 6.8 ng/ml). On the contrary, longer Dex treatments suppress GHRH-induced GH values (6.0 +/- 1.1 ng/ml after Dex 8 mg and 1.8 +/- 0.3 ng/ml after Dex 22 mg). Clonidine administration 300 micrograms p.o. (n = 7) increased GH secretion with an area under the secretory curve (AUC) of 1,274 +/- 236 that was potentiated by Dex 4 mg i.v. given 3 h before clonidine (2,380 +/- 489) and reduced by Dex 8 mg, the reduction being significant only after 22 mg Dex (595 +/- 47).(ABSTRACT TRUNCATED AT 250 WORDS)

Growth hormone and prolactin secretion after growth hormone-releasing hormone administration, in anorexia nervosa patients, normal controls and tamoxifen-pretreated volunteers.

Anorexia nervosa is associated with several abnormalities in GH secretion elicited by different stimuli. To investigate the precise mechanism of this alteration, GHRH was administered to 14 women: a group of eight anorexia nervosa patients in the acute phase of their illness and a control group of six age-matched volunteers. As patients with anorexia nervosa have chronic low oestrogen values, the volunteer women of the control group underwent a second GHRH test after pretreatment with the oestrogen receptor blocker tamoxifen. GHRH 1-29 (1 microgram/kg i.v.) induced a GH peak (mean +/- SEM) of 28.2 +/- 5.1 ng/ml (GH ng/ml x 2 = mU/l) at 30 min in the anorectic patients. This value was no different from the GHRH-stimulated GH peak in the control women (28.1 +/- 10.0 ng/ml). Tamoxifen pretreated women had a GH peak after GHRH of 35.6 +/- 9.7 ng/ml, not significant versus control test. Compared with the control group, oestrogen levels were significantly lower in anorectic patients and higher in tamoxifen-treated women. GHRH administration induced a small PRL peak at 15 min that was similar in the three groups tested. After this 15 min peak, PRL in both anorexic and tamoxifen-treated women returned toward basal values steadily. However, in untreated control women a second PRL peak was evident at 60 min. In conclusion, GHRH-induced GH secretion in anorexia nervosa patients was similar to that in control subjects and in controls under oestrogen receptor blockade.