An inhibition of the hypothalamic somatostatinergic tone is not the cause of the enhanced growth hormone response to growth hormone-releasing hormone in patients with liver cirrhosis.

Animal models of liver cirrhosis (LC) display a reduced hypothalamic somatostatinergic tone. To test whether a similar mechanism could explain the enhanced Growth Hormone (GH) secretory response to GH-Releasing Hormone (GHRH), which is seen in human LC, we studied the effect of the cholinesterase inhibitor pyridostigmine (PD), which is able to reduce the release of hypothalamic somatostatin (SS), on the GHRH-stimulated GH secretion. We considered that if PD were unable to increase GH secretion, this would constitute evidence of an already inhibited endogenous somatostatinergic tone. If proved, this in turn could explain the enhanced GH response to GHRH seen in LC. Ten LC patients and nine controls were given GHRH (100 microg, intravenously), or PD (120 mg, orally) plus GHRH. After GHRH alone, the GH peak was four times higher in LC than in controls (40.85+/-15.7 ng/ml in LC and 9.35+/-2.5 ng/ml in controls). In LC, PD administration markedly increased the GH response to GHRH (GH peak: 98.0+/-19.7 ng/ml; +240% vs. GHRH alone). The ability of PD to increase the GH response in patients with LC suggests that in this condition the enhanced GH response to GHRH is not due to a completely inhibited endogenous somatostatinergic tone. SS appears instead to maintain its modulator role on GH secretion in human LC, in contrast with what observed in animal models.

Interaction of glucose and pyridostigmine on the secretion of growth hormone (GH) induced by GH-releasing hormone (GHRH).

In order to investigate the mechanisms by which hyperglycaemia induces an inhibition of GHRH-induced GH release, we gave the following treatments to seven normal men: a) GHRH 100 micrograms iv; b) pyridostigmine (PD) 120 mg po 60 min before GHRH; c) glucose 250 mg/kg iv as a bolus (10 min before GHRH) plus 10 mg/kg/min until the end of the test; d) glucose pyridostigmine and GHRH as above. Glucose significantly reduced GHRH-stimulated GH levels, whereas PD significantly enhanced them. When PD and glucose were given together, the effect on GHRH-stimulated GH secretion was not different from the algebraic sum of the single effects of the two substances. Thus glucose seems to be able to exert its inhibition, at least partially, also when pyridostigmine is coadministered.

Effect of nifedipine and verapamil on carbohydrate metabolism in hypertensive patients with impaired glucose tolerance.

Intracellular Ca2+ influx is an essential step in insulin (I) release. Calcium antagonists are reported to reduce I release in vitro and in patients with impaired glucose tolerance (IGT) during acute administration. Their effects during long-term therapy are still controversial. To evaluate the effects of chronic verapamil (V) and nifedipine (N) on carbohydrate metabolism, 12 hypertensive patients (WHO II; aged 37-64 years) with IGT underwent intravenous glucose tolerance tests (IVGTT) (0.33 g/kg body weight in 3 min), arginine (A) infusion (30 g/30 min), and hypoglycemic stress (regular insulin 0.15 U/kg body weight) during which blood levels of glucose (G), I, growth hormone (GH), glucagon (IRG), and cortisol (C) were measured. The patients were then randomized to V (120 mg b.i.d.) or N (20 mg b.i.d.) treatment and, 1 month later, both IVGTT and A infusion were repeated. Hormone determinations were performed by the radioimmunoassay (RIA) and G by the enzymatic method. The patients were maintained on their usual diet for the duration of the study. The rate of decline of G during IVGTT was expressed as Conard's K coefficient (K; normal values greater than 1.3). I and GH during IVGTT were evaluated as the differences between basal and peak values. I, IRG, and GH during A infusion were analyzed as incremental areas. Our results show that neither V nor N impaired carbohydrate metabolism in hypertensive patients with IGT.

The participation of hypothalamic dopamine in morphine-induced prolactin release in man.

In order to assess the role of dopamine in opiate-induced prolactin secretion, morphine alone or in combination with the dopamine blocker metoclopramide, or the L-aromatic aminoacid decarboxylase inhibitor benserazide, was administered to a group of normal adult men. Morphine (10 mg) stimulated prolactin release in all subjects; however, the effect was totally abolished when 10 mag metoclopramide or 200 mg benserazide were given before the opiate agonist. The prolactin releasing effect of a sub-maximal metoclopramide dose (1 mg) was potentiated by morphine. In vitro, benserazide was totally inactive in stimulating prolactin release by isolated anterior pituitary cells. Moreover, benserazide failed to alter the inhibiting action of dopamine on prolactin release. The data suggest that opiates stimulate prolactin release in man by acting through dopaminergic mechanisms.

On the role of dopamine receptors in the central regulation of human TSH.

The effects of acute administration of haloperidol (4 mg im) and pimozide (4 mg orally) on TSH and Prl secretion were studied in normal and hypothyroid man. The TRH-induced TSH secretion before and after pre-medication with pimozide and domperidone, a peripheral dopamine (DA) blocker, was also evaluated in a group of normal subjects. Haloperidol and pimozide induced a marked increment in serum Prl; mean Prl levels were still significantly elevated 12 h following pimozide administration. A small but significant TSH increase was observed following haloperidol and pimozide in normal as well as hypothyroid subjects. Both domperidone and pimozide significantly enhanced TRH-induced TSH release. In another experiment 3 women with primary thyroid failure received an infusion of DA (4 micrograms/kg/min for 4 h) with and without domperidone administration. TSH and Prl levels were suppressed by DA, but the effect was completely abolished by domperidone. The results suggest that psychotrophic drugs, such as haloperidol and pimozide, can, like substituted benzamides, stimulate TSH release in man. Since domperidone and DA do not cross the blood-brain-barrier and domperidone significantly enhanced the TSH response to TRH, the data also support the hypothesis that human TSH is regulated by DA at the hypothalamus (median eminence) and/or pituitary level.

Suppression of pimozide-induced prolactin secretion by piridoxine (vitamin B6).

I.V. administration of 300 mg. Pyridoxine caused an acute fall in prolactin (PRL) plasma levels in six normal subjects. Like levodopa, pyridoxine suppressed the increase in PRL secretion induced by treatment with pimozide, a specific dopamine receptor blocking agent. These findings further support the hypothesis that vitamin B6 stimulates dopaminergic activity at hypothalamic and/or hypophyseal level.

Effect of pyridoxine on human hypophyseal trophic hormone release: a possible stimulation of hypothalamic dopaminergic pathway.

A single dose of pyridoxine (300 mg iv) produced significant rises in peak levels of immunoreactive growth hormone GH and significant decrease of plasma prolactin PRL in 8 hospitalized healthy subjects. Serum glucose, luteinizing hormone LH, follicle stimulating hormone FSH and thyrotropin TSH were not altered significantly. In addition, in 5 acromegalic patients who were studied with both L-dopa and pyridoxine, inhibition of GH secretion followed either agent in a similar pattern. These data suggest a hypothalamic dopaminergic effect of pyridoxine.