Ralf-Michael Frieboes

Elevated nocturnal profiles of serum leptin in patients with depression

Leptin, the protein product of the obese (ob) gene, has been suggested to play a role in the regulation of food intake. As depressive episodes are frequently characterized by loss of appetite, reduced food intake and weight loss, altered leptin secretion might also be expected in patients with depression. Therefore, we examined nocturnal (10.00 p.m. to 7.00 a.m.) secretion of leptin, cortisol, ACTH and growth hormone (GH) in a group of 15 patients with depression and age- and sex-matched controls (age range 23-71 years). In addition, the effects of pulsatile administration of growth hormone-releasing hormone (GHRH), thought to be an endogenous antagonist of corticotropin-releasing hormone (CRH), which in turn is believed to play a critical role for the pathophysiology of depression, on nocturnal hormone secretion were assessed. Patients with depression showed a trend towards elevated nocturnal cortisol secretion (F = 3.8, p < 0.05). Nocturnal serum leptin was significantly higher in patients, despite a reported weight loss (F = 8, p < 0.05), but showed the same sexual dimorphism as in controls (F = 20.9, p < 0.01). No significant differences were seen between patients and controls with regard to plasma GH and ACTH. GHRH treatment increased GH secretion in both patients and controls, while the other hormones were not affected. Furthermore, serum leptin was correlated with body mass index (BMI) in controls, but not in patients with depression, supporting an altered regulation of leptin secretion in depressive illness. Finally, we provide some evidence that in young female patients the normal nocturnal leptin surge is blunted. As glucocorticoids can prevent the fasting-induced decline in serum leptin, we propose that hypercortisolism in depression might counteract the reduction in leptin secretion caused by decreased food intake and weight loss. Elevated serum leptin in depression might in turn further promote CRH release, as shown in animals and, hence, contribute to HPA system hyperactivity seen in depression.

Growth hormone-releasing peptide-6 stimulates sleep, growth hormone, ACTH and cortisol release in normal man.

The synthetic hexapeptide growth hormone-releasing peptide (GHRP-6) stimulates growth hormone (GH) release in animals and man. GH-releasing hormone (GHRH) has the same effect. In addition, pulsatile administration of GHRH in normal men results in increased slow-wave sleep (SWS) and blunted cortisol levels. The effect of GHRP on nocturnal hormone secretion and on the sleep electroencephalogram (EEG) is still unknown. We compared the effect of repetitive i.v. boluses (4 x 50 micrograms) of GHRP and placebo (PL) on the sleep EEG (23.00 to 07.00 h) and on the secretion profiles of GH, ACTH and cortisol (20.00 to 07.00 h) in normal male controls. After GHRP, the GH concentration (22.00 to 03.00 h) increased (15.4 +/- 9.6 ng/ml after GHRP vs. 5.5 +/- 4.0 ng/ml after PL, p < 0.02), as did the ACTH level (22.00 to 02.00 h: 21.0 +/- 5.3 pg/ml after GHRP vs. 16.6 +/- 3.1 pg/ml after PL, p < 0.02). During the total night, and particularly during the first half of the night, cortisol secretion was enhanced (22.00 to 03.00 h: 56.0 +/- 31.0 ng/ml after GHRP vs. 25.2 +/- 9.0 ng/ml after PL, p < 0.02). Stage 2 sleep increased (270.1 +/- 25.3 min after GHRP vs. 245.4 +/- 25.8 min after PL, p < 0.02), whereas other sleep-EEG variables including SWS remained unchanged. Our data demonstrate that GHRP stimulates not only GH release but also hypothalamic-pituitary-adrenocortical hormone secretion. The latter effect is opposite to the blunting of cortisol after GHRH. Both GHRP and GHRH promote sleep. However, GHRP enhances stage 2 sleep and does not affect SWS.(ABSTRACT TRUNCATED AT 250 WORDS)

Neuropeptide Y promotes sleep and inhibits ACTH and cortisol release in young men

Anxiolytic and sedative effects of neuropeptide Y (NPY) are thought to involve inhibition of corticotropin-releasing hormone (CRH). Enhanced secretion of CRH plays a critical role in the pathophysiology of major depression, characterized by sleep disturbances, anxiety and loss of appetite. We examined for the first time in young men effects of intravenous injections of NPY (4x50 or 100 microg, n = 9 and 11, respectively, at 22.00, 23.00, 24. 00 and 01.00 compared to saline) on the sleep electroencephalogram (EEG; recorded from 23.00 to 07.00) and nocturnal secretion of adrenocorticotrophic hormone (ACTH), cortisol, growth hormone (GH), prolactin and leptin. Repeated measures MANOVA showed that ACTH secretion during the first half of the night was reduced by the lower dose of NPY only (F = 8.7, p<0.05), while cortisol secretion during the second half of the night was reduced regardless of the dose (F = 7.9, p<0.05). Regardless of the dose, NPY enhanced sleep period time and stage 2 sleep (F = 12.8 and 5.4, each p<0.05), and also reduced sleep latency and time awake (F = 4.9 and 4.4, each p<0.05) and modulated REM sleep. In summary, NPY promotes sleep and inhibits the hypothalamo-pituitary-adrenocortical (HPA) axis in humans, pointing to a possible role of NPY agonists for the development of novel treatment strategies for affective disorders.

Effects of Hormones on Sleep

Administration of hormones to humans and animals results in specific effects on the sleep electroencephalogram (EEG) and nocturnal hormone secretion. Studies with pulsatile administration of various neuropeptides in young and old normal controls and in patients with depression suggest they play a key role in sleep-endocrine regulation. Growth hormone (GH)-releasing hormone (GHRH) stimulates GH and slow wave sleep (SWS) and inhibits cortisol, whereas corticotropin-releasing hormone (CRH) exerts opposite effects. Changes in the GHRH:CRH ratio contribute to sleep-endocrine aberrations during normal ageing and acute depression. In addition, galanin and neuropeptide Y promote sleep, whereas, in the elderly, somatostatin impairs sleep. The rapid eye movement (REM)-nonREM cycle is modulated by vasoactive intestinal polypeptide. Cortisol stimulates SWS and GH, probably by feedback inhibition of CRH. Neuroactive steroids exert specific effects on the sleep EEG, which can be explained by γ-aminobutyric acidA receptor modulation.

Somatostatin impairs sleep in elderly human subjects

With increasing age, sleep becomes more shallow and fragmented and sleep-associated growth hormone (GH) release declines. GH secretion is regulated physiologically by opposite actions of GH-releasing hormone (GHRH) and somatostatin (SRIF). The administration of GHRH promotes sleep in both young and elderly controls, whereas SRIF does not induce sleep-EEG changes in young subjects. Because the influence of peripheral SRIF administration on sleep EEG in the elderly is unknown, we administered 50 μg SRIF-14 every hour between 2200 and 0100 hours to controls with an age range from 60 to 73 years (mean ± SD 67.4 ± 5.1 years). After SRIF administration, total sleep time and rapid eye movement (REM) sleep decreased significantly, and more time was spent awake in the first sleep cycle, suggesting that SRIF induces sleep deterioration in the elderly. The peptide may become more effective on sleep EEG in older than in younger subjects, because of the decline of GHRH–GH axis activity, which may contribute to sleep disturbances in aging. The increased efficacy of SRIF in the elderly also may be explained by enhanced leakage of the blood-brain barrier.

On the Gender Differences in Sleep-Endocrine Regulation in Young Normal Humans

Sleep-endocrine regulation in humans involves high activity of the somatotropic axis at the beginning of the night and an increase in the hypothalamic-pituitary-adrenocortical (HPA) system during the night. Gender differences were examined with regard to sleep-endocrine regulation in young healthy controls (10 men, 9 women). The sleep EEG was recorded (23:00–07:00 h) and plasma samples were collected and analyzed for GH, cortisol and ACTH at 20-min intervals. Cortisol secretion was significantly higher in females during the first half of the night (F = 9.9, p < 0.05), while ACTH was not different. In women, sleep-EEG analysis showed less slow wave sleep (SWS) during the second half of the night (F = 4.5, p < 0.05) and a significantly greater decrease in SWS and delta activity from the first to the second half of the night (F = 3.7 and 7.4, respectively, p < 0.05). Sigma activity increased during the night in women only (F = 3.7, p < 0.05). Our data are compatible with the hypothesis that in women compared to men activity of hypothalamic CRH neurons and central CRH release is greater, but is not reflected by greater HPA activity.

Galanin has REM-sleep deprivation-like effects on the sleep eeg in healthy young men

Rapid eye movement (REM) sleep deprivation leads to an induction of galanin gene expression in the rat brain, especially in the hypothalamus. Galanin affects neuroendocrine systems that are involved in sleep regulation, i.e. the growth hormone-releasing hormone-dependent system of the hypothalamus and the locus coeruleus. In the study reported here we investigated the effects of 4 x 50 microg galanin (n = 10) and of 4 x 150 microg galanin (n = 8) administered hourly between 22.00 and 01.00 h as intravenous boluses on the sleep EEG and nocturnal hormone secretion in healthy young men. Galanin administration significantly increased REM sleep in the third sleep cycle with no difference between the two doses. Spectral analysis revealed a significant increase in the EEG power in the delta and theta frequency range for the total night after the lower dose of galanin, but not after the higher dose. The secretion of growth hormone, cortisol and prolactin remained unchanged during sleep in both cases. Our data are consistent with the assumption of a functional resemblance between the effect of galanin and that of REM sleep deprivation, which is known to have antidepressive efficacy.

Open clinical trial on the sigma ligand panamesine in patients with schizophrenia

Abstract The sigma (σ) receptor has been proposed as a target of neuroleptic drugs. Preclinical data suggest that panamesine (EMD 57445), a novel σ ligand, has antipsychotic effects and is free of side effects related to the extrapyramidal motoric system (EPMS). Here we report the results of an exploratory study aimed at determining the appropriate dose range and the safety of panamesine in patients with an acute episode of schizophrenia. The first trial with four patients revealed insufficient clinical efficacy of a protocol where the daily dosage was increased stepwise from 7.5 mg during week 1, up to 30 mg during weeks 3 and 4. In a second set of trials, 12 patients received 15 mg at the beginning, this being increased up to 60 mg/day within 3 days and then maintained at this level for 4 weeks. As assessed by a decrease in the Brief Psychiatric Rating Scale score by at least 50%, five patients were judged as responders, whereas six patients showed only a slight improvement, and one deteriorated. Moreover, intent-to-treat analysis showed significant improvement in psychometric variables. In all patients prolactin levels increased during treatment, probably due to an active metabolite with weak dopamine-2-receptor antagonistic effects. No major side effects occurred, and in particular, no EPMS symptoms were seen.

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.

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.