Sleep-endocrine effects of growth hormone-releasing hormone (GHRH) in patients with schizophrenia.

Changes in sleep-EEG after endocrine stimulation tests in patients with schizophrenia include reduced sleep efficiency, prolonged sleep latency and increased awaking after sleep onset Findings on sleep associated growth hormone (GH) secretion were ambiguous. The aim of this study was to elucidate the sleep-endocrine activity especially in the GH system of patients with schizophrenia after repeated administration of GHRH. The effect of repetitive injections of 4 × 50 µg GHRH between 22.00 and 01.00 h on sleep endocrine parameters was investigated in 9 patients diagnosed for schizophrenia. Patients did not receive any medication for one week. Concentrations of ACTH, cortisol, prolactin and GH were determined. Patients spent three consecutive nights in the sleep laboratory. Blood was taken every 20min. Results were compared with matched healthy controls. A non-significant prolonged sleep onset latency and increased time awake was found in patients compared to controls. Sleep stage 2 was significantly reduced in patients. No significant difference in ACTH and cortisol was detected, whereas the GH secretion in patients following GHRH stimulation was significantly elevated compared to controls. Our results in drug free patients confirm already known changes in sleep-EEG in these patients. The GH response to GHRH-stimulation indicates a different regulatory sensitivity of the system between daytime and night-time.

Outcome in delusional depression comparing trimipramine monotherapy with a combination of amitriptyline and haloperidol--a double-blind multicenter trial.

BACKGROUND: Patients with delusional depression are difficult to treat. The atypical antidepressant trimipramine was effective in a previous 4-week open label pilot study in patients with this disorder. The major neurobiological effect of trimipramine is the inhibition of the hypothalamic-pituitary-adrenocortical (HPA) system. In delusional depression HPA overactivity is more distinct than in other subtypes of depression. HPA suppression is thought to contribute to the action of trimipramine. METHODS: In a double-blind, randomized, placebo controlled multicenter trial we compared the effects of trimipramine monotherapy versus a combination of amitriptyline and haloperidol. Dosage was increased stepwise from 100mg up to 400mg trimipramine and from 100mg up to 200mg amitriptyline combined with 2mg up to 7.5mg haloperidol. The average dose of trimipramine was higher than that of amitriptyline throughout the trial. During sixth week mean dosage (+/-standard deviation) were 356.1+/-61.2mg trimipramine, 184.0+/-23.6 mg amitriptyline and 6.3+/-1.8 mg haloperidol. During six weeks psychometric assessments were performed weekly. For HPA monitoring a dexamethasone/corticotropin-releasing hormone (Dex/CRH) test was performed before active medication and at the end of treatment. Additionally tolerability was monitored by ECG, EEG assessment of extrapyramidal symptoms and akathisia, clinical laboratory routine and recording of blood pressure and heart rate. Adverse events were documented. RESULTS: 94 patients were enclosed into the study. The per protocol sample consisted of 33 patients of the trimipramine group and of 24 patients of the amitriptyline/haloperidol group. The decrease of the Hamilton depression (HAMD) score (24 items) showed non-inferiority of trimipramine compared to amitriptyline/haloperidol. Twenty-eight patients (84.84%) in the trimipramine arm and 17 patients (70.83%) in the amitriptyline/haloperidol arm were responders (HAMD

Systemic growth hormone-releasing hormone (GHRH) impairs sleep in healthy young women.

In young male subjects peripherally administered growth hormone-releasing hormone (GHRH) enhances GH and slow wave sleep (SWS) and blunts cortisol. In contrast, in a sample of females 19-76-year old, GHRH impairs sleep and enhances adrenocorticotropic hormone (ACTH) and cortisol. In the latter study, the days of investigation were not adapted to the menstrual cycle and premenopausal and postmenopausal women as well were included. Placebo and GHRH were given during consecutive nights. In order to confirm or reject the sexual dimorphism of the effects of GHRH on sleep we applied an improved study design. In the present study we examined the effect of pulsatile administration of two dosages of GHRH (4x25 or 4x50 microg intravenously, respectively) on sleep electroencephalogram (EEG) and nocturnal hormone secretion in healthy young women according to a randomized schedule. To rule out the influence of gonadal hormone activity, the study was adapted to the phase of the menstrual cycle and was performed at 4-6th day of menstrual cycle. A carry-over effect was excluded by the interval of at least 4 weeks between examinations. Compared to placebo rapid-eye-movement sleep decreased during the first half of the night after 4x25 microg GHRH and sleep stage 4 decreased after 4x50 microg GHRH. After both dosages GH increased whereas ACTH and cortisol remained unchanged. This study confirms that systemic GHRH impairs sleep in women.

Neuropeptide Y (NPY) shortens sleep latency but does not suppress ACTH and cortisol in depressed patients and normal controls.

Preclinical and clinical studies suggest that neuropeptide Y (NPY) exerts functional corticotropin-releasing hormone (CRH) antagonistic effects. NPY activity appears to be blunted in depression. Recently, we have found in young normal male controls after repetitive administration of NPY a shortened sleep latency and a decrease of time awake and, in the second half of the night, EEG delta-power; cortisol and ACTH levels were blunted. Since during depression there is an overactivity of CRH, we tested the capacity of NPY to affect sleep endocrine activity in patients with depression compared with controls. After one night of adaptation we administered hourly IV injections of placebo (PL) during the second night and of 50 microg NPY during the third night between 22:00 and 01:00 h. Throughout the night ACTH, cortisol and prolactin levels were measured, simultaneously the sleep electroencephalogram (EEG) was recorded. Depressed patients as well as healthy controls exhibited significant shortening of sleep onset latency (SOL) (mean+/-SD; controls: 41.9+/-48.2 min PL vs 22.1+/-17.3 min NPY; patients: 31.8+/-19.8 min PL vs 24.7+/-20.1 min NPY; P<0.06) and REM latency (controls: 79.3+/-27.5 min PL vs 69.0+/-19.4 min NPY; patients: 79.8+/-45.5 min PL vs 52.4+/-51.2 min NPY; P<0.05). Both patients and controls showed a trend to an increase of prolactin during the night. In contrast to our recent observation in young normal subjects time awake, ACTH and cortisol remained unchanged in patients and controls in response to NPY. Whereas also an adaptation effect may contribute to the shortening of SOL, this change and the prolactin elevation are in line with a CRH antagonistic and GABA(A) agonistic/benzodiazepine-like effect of NPY. The lack of effects on time awake and HPA hormones may be explained by the higher CRH activity due to age and depression in the investigated samples in comparison to our recent study in young subjects.

Changes of sleep architecture, spectral composition of sleep EEG, the nocturnal secretion of cortisol, ACTH, GH, prolactin, melatonin, ghrelin, and leptin, and the DEX-CRH test in depressed patients during treatment with mirtazapine.

The noradrenergic and specific serotoninergic antidepressant mirtazapine improves sleep, modulates hormone secretion including blunting of hypothalamic-pituitary-adrenocortical (HPA) activity, and may prompt increased appetite and weight gain. The simultaneous investigation of sleep electroencephalogram (EEG) and hormone secretion during antidepressive treatment helps to further elucidate these effects. We examined sleep EEG (for later conventional and quantitative analyses) and the nocturnal concentrations of cortisol, adrenocorticotropin (ACTH), growth hormone (GH), prolactin, melatonin and the key factors of energy balance, ghrelin, and leptin before and after 28 days of treatment of depressed patients (seven women, three men, mean age 39.9+/-4.2 years) with mirtazapine. In addition, a sleep EEG was recorded at day 2 and the dexamethasone-corticotropin-releasing hormone (DEX-CRH) test was performed to assess HPA activity at days -3 and 26. Psychometry and mirtazapine plasma concentrations were measured weekly. Already at day 2, sleep continuity was improved. This effect persisted at day 28, when slow-wave sleep, low-delta, theta and alpha activity, leptin and (0300-0700) melatonin increased, and cortisol and ghrelin decreased. ACTH and prolactin remained unchanged. The first two specimens of GH collected after the start of quantitative EEG analysis were reduced at day 28. The DEX-CRH test showed, at day 26, a blunting of the overshoot of ACTH and cortisol found at day -3. The Hamilton Depression score decreased from 32.1+/-7.3 to 15.5+/-6.7 between days -1 and 28. A weight gain of approximately 3 kg was observed. This unique profile of changes is compatible with the action of mirtazapine at 5-HT-2 receptors, at presynaptic adrenergic alpha 2 receptors, at the HPA system, and on ghrelin and leptin.

Alpha-helical CRH exerts CRH agonistic effects on sleep-endocrine activity in humans.

CRH is known to enhance wakefulness and to reduce SWS. In addition, some but not all, studies suggest that CRH promotes REM sleep. Alpha-helical CRH exerts CRH-antagonistic effects in various studies. We studied its effect on sleep EEG and nocturnal secretion of ACTH, cortisol, GH (n = 7) in young normal male subjects. After administering the substance cortisol and ACTH levels were enhanced during the total night compared to placebo. We found an increase of the time spent awake for the first half. ACTH (2nd half of the night) and cortisol (total night and 1st half of the night) increased. The results of the present study correspond to a mixture of agonistic and antagonistic effects of alpha-helical CRH.

Ghrelin stimulates appetite, imagination of food, GH, ACTH, and cortisol, but does not affect leptin in normal controls.

Ghrelin, a growth hormone (GH) secretagogue receptor ligand was isolated from the stomach and hypothalamus of rats and humans. In rodents, ghrelin exerts distinct orexigenic action, probably as counterpart of the anorexigenic leptin. In humans, ghrelin infusion enhances appetite. It is unknown whether single intravenous (i.v.) injections of ghrelin affect human eating behavior. Therefore, we investigated the influence of a single i.v. bolus injection of 100 microg ghrelin on appetite, ideas about food, hormone levels, and glucose concentration in young control subjects. In order to test gender differences, we included five women and four men. After ghrelin administration, appetite was enhanced in eight of nine subjects. Seven probands reported a vivid, plastic image of their preferred meal. Furthermore, ghrelin stimulated an immediate increase in plasma levels of GH (area under the curve, mean+/-SEM 35+/-16 ng/ml x min after placebo [P] to 2808+/-533 ng/ml x min after ghrelin [G]; p<0.001), cortisol (5908+/-984 ng/ml x min [P] to 10179+/-1293 ng/ml x min [G]; p<0.001), and ACTH (922+/-103 pg/ml x min [P] to 3030+/-763 pg/ml x min [G]; p<0.02), whereas leptin levels remained unchanged. Contrary to placebo, glucose concentration did not decrease markedly after administration of ghrelin. Our data suggest that i.v. ghrelin stimulates appetite and images of food in young women and men. Obviously, leptin is not involved in these effects.

Changes in sleep electroencephalogram and nocturnal hormone secretion after administration of the antidyskinetic agent sarizotan in healthy young male volunteers.

RATIONALE: Sarizotan is a 5-HT(1A) agonist with high affinity to D(3) and D(4) receptors. In animal experiments, the drug shows a strong anti-cataleptic effect and suppresses effectively dyskinesias in animal models of L: -dopa-induced dyskinesia and of tardive dyskinesia. Data from an open pilot study in patients with Parkinson's disease show clear indication of a treatment effect against L: -dopa-induced dyskinesia. OBJECTIVE: CNS-active drugs are known to modulate sleep electroencephalogram (EEG) and sleep-related hormone secretion. 5-HT(1A) agonists suppress rapid-eye movement (REM) sleep and enhance the secretion of ACTH, cortisol, prolactin and growth hormone (GH) at daytime. We hypothesised that sarizotan shares these effects. Furthermore, we were interested in the influence of sarizotan on leptin, which participates in the regulation of the energy balance and is enhanced after various psychoactive drugs. METHODS: Ten healthy male subjects were investigated twice in a double-blind, placebo-controlled crossover design. Sleep EEG and nocturnal hormone secretion of ACTH, cortisol, prolactin, GH and leptin were examined after oral administration of either placebo or 20 mg of sarizotan at night. RESULTS: After administration of sarizotan, a significant reduction of REM sleep and total sleep time in conventional sleep EEG and a significant reduction of sigma- and theta-power in spectral analysis were observed. The main effect on nocturnal hormone secretion was a significant elevation of prolactin and of ACTH in the first half of the night. CONCLUSIONS: While REM sleep was suppressed, the endocrine effects of 20 mg sarizotan at night were weak. Its sleep-endocrine profile is comparable to the effects provoked by selective 5-HT reuptake inhibitors.

Intravenous administration of the neuropeptide galanin has fast antidepressant efficacy and affects the sleep EEG.

OBJECTIVE: Recently, we demonstrated that the intravenous administration of the neuropeptide galanin acts on the sleep EEG of healthy young subjects similar to sleep deprivation. As this effect could imply an antidepressive potency we studied the effect of intravenous galanin administration on psychopathology and sleep EEG in patients with depression. METHODS: Galanin was administered to 10 patients with depression, who were on a stable dose of trimipramine. A placebo controlled double blind randomized design was used. Intravenous boli of galanin in a dose of 4 x 50 microg or placebo were administered hourly between 09:00 and 12:00 h. Galanin or placebo, respectively were administered on 2 days each. The sequence of the galanin or placebo days was randomized, allowing for various crossovers. The Hamilton depression rating scale score (HAMD) was performed 30 min before the first and 30 min after the last injection. The mean of the HAMD change between 08:30 and 12:30 h was chosen as primary efficacy variable. Sleep EEGs were recorded once post placebo treatment and once post verum treatment. In this case, recordings started at 23:00 h and ended at 07:00 h the next morning. RESULTS: The HAMD-difference between 08:30 and 12:30 h was significantly greater at the days of galanin-treatment compared to placebo-treatment. MANOVA revealed a significant change in sleep-EEG parameters (p < 0.05), mainly due to an increase in REM-latency (p < 0.06). CONCLUSION: The data provide preliminary evidence for an acute antidepressive efficacy of galanin, probably by a mechanism related to that of therapeutic sleep deprivation.

Hexarelin decreases slow-wave sleep and stimulates the secretion of GH, ACTH, cortisol and prolactin during sleep in healthy volunteers.

Ghrelin, the endogenous ligand of the growth hormone (GH) secretagogue (GHS) receptor and some GHSs exert different effects on sleep electroencephalogram (EEG) and sleep-related hormone secretion in humans. Similar to GH-releasing hormone (GHRH) ghrelin promotes slow-wave sleep in humans, whereas GH-releasing peptide-6 (GHRP-6) enhances stage 2 nonrapid-eye movement sleep (NREMS). As GHRP-6, hexarelin is a synthetic GHS. Hexarelin is superior to GHRH and GHRP-6 in stimulating GH release. The influence of hexarelin on sleep-endocrine activity and the immune system is unknown. We investigated simultaneously the sleep EEG and nocturnal profiles of GH, ACTH, cortisol, prolactin, leptin, tumor necrosis factor (TNF)-alpha, and soluble TNF-alpha receptors in seven young normal volunteers after repetitive administration of 4 x 50 microg hexarelin or placebo at 22.00, 23.00, 24.00 and 01.00 h. Following hexarelin, stage 4 sleep during the first half of the night, and EEG delta power during the total night decreased significantly. Significant increases of the concentrations of GH and prolactin during the total night, and of ACTH and of cortisol during the first half of the night were found. Leptin levels, TNF-alpha and soluble TNF receptors remained unchanged. We hypothesize that sleep is impaired after hexarelin since the GHRH/corticotropin-releasing hormone (CRH) ratio is changed in favour of CRH. There are no hints for an interaction of hexarelin and the immune system.

The renin-angiotensin-aldosterone system in patients with depression compared to controls--a sleep endocrine study.

BACKGROUND: Hypercortisolism as a sign of hypothamamus-pituitary-adrenocortical (HPA) axis overactivity and sleep EEG changes are frequently observed in depression. Closely related to the HPA axis is the renin-angiotensin-aldosterone system (RAAS) as 1. adrenocorticotropic hormone (ACTH) is a common stimulus for cortisol and aldosterone, 2. cortisol release is suppressed by mineralocorticoid receptor (MR) agonists 3. angiotensin II (ATII) releases CRH and vasopressin from the hypothalamus. Furthermore renin and aldosterone secretion are synchronized to the rapid eyed movement (REM)-nonREM cycle. METHODS: Here we focus on the difference of sleep related activity of the RAAS between depressed patients and healthy controls. We studied the nocturnal plasma concentration of ACTH, cortisol, renin and aldosterone, and sleep EEG in 7 medication free patients with depression (1 male, 6 females, age: (mean +/-SD) 53.3 +/- 14.4 yr.) and 7 age matched controls (2 males, 5 females, age: 54.7 +/- 19.5 yr.). After one night of accommodation a polysomnography was performed between 23.00 h and 7.00 h. During examination nights blood samples were taken every 20 min between 23.00 h and 7.00 h. Area under the curve (AUC) for the hormones separated for the halves of the night (23.00 h to 3.00 h and 3.00 h to 7.00 h) were used for statistical analysis, with analysis of co variance being performed with age as a covariate. RESULTS: No differences in ACTH and renin concentrations were found. For cortisol, a trend to an increase was found in the first half of the night in patients compared to controls (p < 0.06). Aldosterone was largely increased in the first (p < 0.05) and second (p < 0.01) half of the night. Cross correlations between hormone concentrations revealed that in contrast to earlier findings, which included only male subjects, in our primarily female sample, renin and aldosterone secretion were not coupled and no difference between patients and controls could be found, suggesting a gender difference in RAAS regulation. No difference in conventional sleep EEG parameters were found in our sample. CONCLUSION: Hyperaldosteronism could be a sensitive marker for depression. Further our findings point to an altered renal mineralocorticoid sensitivity in patients with depression.

Oral Mg(2+) supplementation reverses age-related neuroendocrine and sleep EEG changes in humans.

The process of normal aging is accompanied by changes in sleep-related endocrine activity. During aging, an increase in cortisol at its nadir and a decrease in renin and aldosterone concentration occur. In aged subjects, more time is spent awake and slow-wave sleep is reduced: there is a loss of sleep spindles and accordingly a loss of power in the sigma frequency range. Previous studies could show a close association between sleep architecture, especially slow-wave sleep, and activity in the glutamatergic and GABAergic system. Furthermore, recent studies could show that the natural N-methyl-D-aspartate (NMDA) antagonist and GABA(A) agonist Mg(2+) seems to play a key role in the regulation of sleep and endocrine systems such as the HPA system and renin-angiotensin-aldosterone system (RAAS). Therefore, we examined the effect of Mg(2+) in 12 elderly subjects (age range 60-80 years) on the sleep electroencephalogram (EEG) and nocturnal hormone secretion. A placebo-controlled, randomised cross-over design with two treatment intervals of 20 days duration separated by 2 weeks washout was used. Mg(2+) was administered as effervescent tablets in a creeping dose of 10 mmol and 20 mmol each for 3 days followed by 30 mmol for 14 days. At the end of each interval, a sleep EEG was recorded from 11 p.m. to 7 a.m. after one accommodation night. Blood samples were taken every 30 min between 8 p.m. and 10 p.m. and every 20 min between 10 p.m. and 7 a.m. to estimate ACTH, cortisol, renin and aldosterone plasma concentrations, and every hour for arginine-vasopressin (AVP) and angiotensin 11 (ATII) plasma concentrations. Mg(2+) led to a significant increase in slow wave sleep (16.5 +/- 20.4 min vs. 10.1 +/- 15.4 min, < or =0.05), delta power (47128.7 microV(2) +21417.7 microV(2) vs. 37862.1 microV(2) +/- 23241.7 microV(2), p < or =0.05) and sigma power (1923.0 microV(2) + 1111.3 microV(2) vs. 1541.0 microV(2) + 1134.5 microV(2), p< or =0.05 ). Renin increased (3.7 +/- 2.3 ng/ml x min vs. 2.3 +/- 1.0 ng/ml x min, p < 0.05) during the total night and aldosterone (3.6 +/- 4.7 ng/ml x min vs. 1.1 +/- 0.9 ng/ml x min, p < 0.05) in the second half of the night, whereas cortisol (8.3 +/- 2.4 pg/ml x min vs. 11.8 +/- 3.8 pg/ml x min, p < 0.01) decreased significantly and AVP by trend in the first part of the night. ACTH and ATII were not altered. Our results suggest that Mg(2+) partially reverses sleep EEG and nocturnal neuroendocrine changes occurring during aging. The similarities of the effect of Mg(2+) and that of the related electrolyte Li+ furthermore supports the possible efficacy of Mg(2+) as a mood stabilizer.

Nocturnal secretion of TSH and ACTH in male patients with depression and healthy controls.

Profound alterations of the hypothalamic-pituitary-thyroid (HPT) and the hypothalamic-pituitary-adrenal (HPA) systems at the hypophyseal level have been described in affective disorder. To precisely characterize the basal alterations of both axes during sleep, we simultaneously investigated sleep EEG and the secretion of thyrotropin, ACTH and cortisol in nine drug-free male patients with depression in comparison to 10 healthy age and sex matched controls. In depressed patients the nearly diametrical nocturnal secretion of thyrotropin and ACTH was disturbed by significantly blunted thyrotropin values (TSH AUC 51.96+/-5.68 vs. 87.23+/-13.63, P<0.05) and elevated ACTH values (ACTH AUC 1804+/-161 vs. 1538+/-130, P<0.05) compared to controls. Moreover, cross correlation analysis revealed a highly negative association of 0 lag between thyrotropin and ACTH and between thyrotropin and cortisol in the control sample, indicating a physiological nocturnal negative correlation of HPT and HPA system. In the patients sample these associations were weak and reached not statistical significance. Therefore, as a descriptive tool, the ratio TSH/ACTH revealed a significant group difference between controls and patients in the first half of the night (TSH/ACTH AUC 6.50+/-0.42 vs. 3.35+/-0.31, P<0.05). Sleep-EEG analysis showed a shortened REM latency, a decrease of stage 2 and an increase of awake time in the patients. Our data support the hypothesis that both hypophyseal hormones reflect a common dysregulation of both systems in depression probably due to impaired action of TRH-related corticotropin-release-inhibiting-factor (CRIF). The ratio TSH/ACTH might be a tool to characterize alterations of both the HPT and HPA axis in depression during the first half of the night.