Enhanced slow wave sleep in patients with prolactinoma.

Bidirectional interactions between nocturnal hormone secretion and sleep regulation are well established. In particular, a link between PRL and rapid eye movement (REM) sleep has been hypothesized. Short-term administration of PRL and even long-term hyperprolactinemia in animals increases REM sleep. Furthermore, sleep disorders are frequent symptoms in patients with endocrine diseases. We compared the sleep electroencephalogram of seven drug-free patients with prolactinoma (mean PRL levels 1450 +/- 1810 ng/mL; range between 146 and 5106 ng/mL) with that of matched controls. The patients had secondary hypogonadism but no other endocrine abnormalities. They spent more time in slow wave sleep than the controls (79.4 +/- 54.4 min in patients vs. 36.6 +/- 23.5 min in controls, P < 0.05). REM sleep variables did not differ between the samples. Our data suggest that chronic excessive enhancement of PRL levels exerts influences on the sleep electroencephalogram in humans. Our result, which seems to be in contrast to the enhanced REM sleep under hyperprolactinemia in rats, leads to the hypothesis that both slow wave sleep and REM sleep can be stimulated by PRL. These findings are in accordance with reports of good sleep quality in patients with prolactinoma, which is in contrast to that of patients with other endocrine diseases.

Aging does not affect the sleep endocrine response to total sleep deprivation in humans.

Aging is associated with decreased sleep continuity, slow wave sleep (SWS), growth hormone (GH) release and an increased hypothalamo-pituitary-adrenocortical (HPA) system activity. Total sleep deprivation (TSD) is a strong stimulus for sleep. To determine if aging affects the response to TSD, for the first time the combined effects of TSD on conventional and spectral sleep electroencephalographic (EEG) parameters and GH, cortisol and prolactin secretion were compared in elderly (60-80 years; n = 7) vs. younger subjects (20-30 years; n = 7). MANOVA revealed a reduction of SWS in the elderly. TSD led to an increase in SWS, a decrease in sleep onset latency, rapid eye movement (REM) density and by trend REM-latency without a global group difference. GH was reduced, whereas prolactin was enhanced in the elderly. After TSD GH was unchanged and prolactin secretion was enhanced without group difference. Thus, the plasticity of the sleep-endocrine system in response to TSD is sustained during aging. The possible involvement of the GABAergic system, that seems not to be severely impaired with age, is proposed.

Prediction of medium-term outcome by cortisol response to the combined dexamethasone-CRH test in patients with remitted depression.

OBJECTIVE: Current hypotheses hold that mechanisms underlying abnormal hypothalamic-pituitary-adrenocortical (HPA) function are causal factors in the precipitation of depression. If this is the case, then normalization of initially disturbed HPA regulation should indicate a good prognosis and persistent HPA dysregulation should be associated with a greater likelihood of relapse or chronicity. METHOD: The combined dexamethasone/corticotropin-releasing hormone test was administered twice to inpatients with major depression (N = 40), once after initiation of treatment and once after remission, shortly before discharge. RESULTS: Patients with a high cortisol response on both occasions or with a substantially increased cortisol response at discharge were at much higher risk for relapse within the next 6 months than those with low cortisol responses. CONCLUSIONS: An easy-to-administer neuroendocrine test allows the prediction of medium-term outcome in patients with remitted depression.

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 micrograms 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.

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.

Lack of association between schizophrenia and the phospholipase-A(2) genes cPLA2 and sPLA2.

The well-established role of genetic factors in the etiology of schizophrenia together with reports of allelic association with cPLA2, a phospholipase-A(2) gene, a reported increase of phospholipase-A(2) activity, and the phospholipase-A(2) hypothesis of Horrobin et al. [1995: Med Hypotheses 45:605-613] strongly support cPLA2 (PLA2G4A) and sPLA2 (PLA2G1B) as candidate genes for schizophrenia. In search for allelic association between these phospholipase-A(2) genes and schizophrenia, two samples of Chinese and European origins, in total 328 unrelated schizophrenic patients and their parents, were investigated using Falk and Rubinstein's haplotype relative risk method. Both genes showed marginally significant evidence for association in the total sample (P

On the role of menopause for sleep-endocrine alterations associated with major depression.

Aging and menopause are associated with alterations of the sleep EEG, while age-related changes of the hypothalamo-pituitary-adrenal (HPA) axis remain controversial. Major depression is also associated with typical sleep-endocrine changes, including enhanced activity of the HPA axis, while an influence of age and gender on these alterations is less clear. To test the hypothesis that after menopause sleep-endocrine alterations associated with major depression are accentuated, we examined the sleep EEG and nocturnal hormone secretion (ACTH, cortisol, GH, estradiol, LH, FSH, and leptin) in 16 drug-free female patients, mostly with the first episode of a major depressive disorder (seven pre- and nine postmenopausal subjects) and 19 female controls (10 subjects in the early follicular phase and nine postmenopausal subjects). Nocturnal cortisol secretion was increased in postmenopausal patients with depression, while a decrease was noted in postmenopausal controls. Sleep alterations typically associated with depression, namely a reduction in sleep continuity and slow wave sleep (SWS) and an increase in REM density, were prominent in post- but not in premenopausal patients. An inverse correlation was noted between the decline in SWS and sleep continuity and FSH secretion in patients with depression, suggesting a role of menopause for these sleep-endocrine alterations typically associated with major depression. In contrast, in premenopausal patients we noted primarily a shift in SWS and delta-EEG activity from the first to the second non-REM period, which was not related to age or hormone secretion. Though the relatively small number of subjects per group precludes a definitive conclusion, our data open up the possibility that the sleep-endocrine changes typically associated with major depression are most prominent in postmenopausal patients. Whether the predominant alteration of the distribution of SWS and delta EEG activity in younger patients with a first episode of major depression has a predictive value for the future course of the disease remains to be investigated.

Effects of growth hormone-releasing peptide-6 on the nocturnal secretion of GH, ACTH and cortisol and on the sleep EEG in man: role of routes of administration.

After repeated intravenous (i.v.) boluses of growth hormone-releasing peptide-6 (GHRP-6) we found recently increases of growth hormone (GH), corticotropin (ACTH) and cortisol levels and of the amount of stage 2 sleep. In clinical use, oral (p.o.), intranasal (i.n.) and sublingual (s.l.) routes of administration have advantages over i.v. administration. We compared the sleep-endocrine effects of 300 microg/kg of body weight (b.w.) GHRP-6 in enteric-coated capsules given p.o. at 21.00 h and of 30 microg/kg GHRP-6 i.n. or 30 microg/kg GHRP-6 sl. given at 22.45 h in normal young male controls with placebo conditions. After GHRP-6 p.o. secretion of GH, ACTH and cortisol remained unchanged. The only effect of GHRP-6 s.l. was a trend toward an increase in GH in the first half of the night. GHRP-6 i.n. prompted a significant increase in GH concentration during the total night and a trend toward an increase in ACTH secretion during the first half of the night, whereas cortisol secretion remained unchanged. Furthermore, after GHRP-6 i.n., sleep stage 2 increased in the second half of the night by trend, and spectral analysis of total night non-rapid eye movement (REM) sleep revealed a decrease of delta power by trend. In contrast sleep stage 2 decreased during the second half of the night after GHRP-6 p.o. Our data demonstrate that GHRP-6 is capable of modulating GH and ACTH secretion as well as sleep. However, the effects depend upon dosage, duration and route of administration.

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

The sigma (sigma) receptor has been proposed as a target of neuroleptic drugs. Preclinical data suggest that panamesine (EMD 57445), a novel sigma 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.

Distinct temporal pattern of the effects of the combined serotonin-reuptake inhibitor and 5-HT1A agonist EMD 68843 on the sleep EEG in healthy men.

RATIONALE: EMD 68843 (EMD) has properties of a serotonin (5-HT)-reuptake inhibitor and a partial 5-HT1A agonist in one molecule in order to combine antidepressive and anxiolytic properties. OBJECTIVE: We investigated the effects of EMD on the sleep EEG in order to characterize how the complex interaction between these two properties influences the sleep EEG. METHODS: We performed a randomized crossover study in ten young normal male controls (20-30 years), receiving a single dose of 20 mg EMD or placebo orally at 2100 hours. Sleep EEG was recorded from 2300 to 0700 hours. RESULTS: After EMD, rapid eye movement (REM) sleep was nearly totally abolished. In the course of the night other effects on the sleep EEG occurred in distinct intervals. Slow wave sleep and EEG delta power increased in the first and third one-third of the night, whereas wakefulness was enhanced in the second and third one-third of the night. CONCLUSION: The sleep EEG effects of EMD fit with its pharmacological profile, which might lead to adaptive changes suggested to characterize an antidepressive substance.

Characterization of the sigma ligand panamesine, a potential antipsychotic, by immune response in patients with schizophrenia and by sleep-EEG changes in normal controls.

Panamesine (PAN) is a nearly specific sigma ligand. Recently, we showed that PAN in doses up to 90 mg/day improved psychometric variables in patients with an acute episode of schizophrenia. No side effects connected to the extrapyramidal motoric system occurred; there was even an absence of daytime sedation. We investigated the effects of PAN on plasma cytokine and soluble cytokine receptor levels and blood cell counts during 4 weeks in ten patients out of the previous study sample. Under PAN treatment, tumor necrosis factor (TNF)-alpha, soluble TNF receptors p55 and p75, and soluble interleukin-2 receptor levels were not increased and neither were monocyte and lymphocyte counts affected. This absence of immunomodulation is in contrast to clozapine, but similar to haloperidol treatment. In a second study, a single dose of PAN (30 mg) or placebo was administered at 2200 hours to ten young male controls in order to investigate changes in the sleep EEG under the substance. Sleep efficiency index increased, whereas time spent awake decreased. No significant changes in rapid eye movement (REM) sleep or non-REM parameters occurred. The sleep-EEG investigation showed sleep-consolidating effects of the drug, comparable to those of classical neuroleptics. Our results support the hypothesis that the sigma ligand PAN, which has antipsychotic properties, shares biological aspects with haloperidol.

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.

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.

[Sociotherapy in German social law. Indication, contents, and aspects of public health]. / Soziotherapie gemäss Paragraph 37a SGB V. Psychiatrische Indikation, Leistungsbeschreibung und sozialrechtlicher Hintergrund.

In German mental health services, the ill-defined term "sociotherapy" has been used to designate nonmedical, social, and work-related components of the care process. Recently, a new component of outpatient/community mental health care called "sociotherapy" (according to Paragraph 37a of the Fifth German Social Code) which is funded by the public health insurance system has been introduced and is now in the process of being implemented. The paper describes (a) patients eligible for the service and (b) the aims and scope of this case management module. The key objectives are to motivate patients with schizophrenia to utilise mental health services and antipsychotic medication and to liaise with psychosocial services. Therefore, sociotherapy is distinct from (a) multidisciplinary inpatient care for people with severe mental illness, (b) assertive community treatment, (c) community care provided by social workers or community psychiatric nurses, and (d) family interventions. So far there has been little evaluation of sociotherapy.

Longtime administration of growth hormone-releasing hormone (GHRH) does not restore the reduced efficiency of GHRH on sleep endocrine activity in 2 old-aged subjects--a preliminary study.

Aging results in a more shallow sleep accompanied by a blunted growth hormone (GH) secretion. In young male normal controls repetitive administration of GH-releasing hormone (GHRH) at the beginning of the night results in an increased secretion of GH, a blunting of cortisol and a stimulation of slow-wave sleep (SWS). In healthy elderly men and women, however, GHRH exerts only weak effects on sleep-endocrine activity. In a previous report continuous treatment of healthy elderly males by repetitive administration of GHRH (during 12 days administration with 100 micrograms GHRH i.v. at 9.00 h every second day, "priming") enhanced GHRH stimulated GH secretion at daytime markedly. We tested if priming with GHRH results in a more distinct modulation of the nocturnal hormone secretion and of the sleep EEG than acute administration of the peptide. Two elderly male controls spent first three consecutive nights in the sleep laboratory, the first of which served for adaptation to laboratory conditions. During the two other nights (at days 1 and 2) sleep EEG was recorded and blood was sampled for determining the secretion of GH, cortisol and ACTH. In one of the nights the subjects received 50 micrograms GHRH hourly between 22.00 h and 1.00 h (4 x 50 micrograms) or placebo. The next examination followed after the priming period at day 14 and the last was performed two weeks after treatment at day 28. After the baseline administration of 4 x 50 micrograms GHRH before priming no clear changes of sleep EEG towards improved sleep were detectable, whereas GH secretion was increased. After priming sleep period time and SWS time were lower compared to the baseline night with GHRH administration, whereas REM time duration increased. GHRH induced GH secretion was not enhanced after priming. ACTH secretion was markedly enhanced compared to baseline stimulation. We conclude that priming with GHRH has no sleep improving effect and does not change hormone secretion in elderly normal subjects. Hence in the elderly priming with GHRH is not capable to induce a rejuvenation of sleep endocrine activity.

[Symptomatic acoustic hallucinations after traumatic brain damage. Review of the literature and case report]. / Symptomatische akustische Halluzinose nach traumatischer Hirnschädigung. Literaturübersicht und Fallbericht.

Symptomatic hallucinosis can be observed after subcortical lesions of different localisation with a predominance of complex-visual perceptive disturbances. Only single cases with complex acoustic hallucinosis have been reported in the literature. A 30-year-old patient is presented who suffered from a midbrain syndrome after severe traumatic brain injury and developed an acoustic hallucinosis in the chronic stage of rehabilitation. The functional relevance and therapeutic strategies are considered with regard to the relevant literature.

[The role of neuropeptides in normal and disordered sleep regulation]. / Die Rolle von Neuropeptiden in der normalen und gestörten Schlafregulation.

The neuropeptides growth hormone-releasing hormone (GHRH) and corticotropin-releasing hormone (CRH) play a key role in sleep endocrine regulation. After pulsatile application of GHRH during the first few hours of the night in young normal controls SWS and GH increase, whereas cortisol is blunted. CRH however prompts inverse effects. The balance between these peptides is changed in favour of CRH physiologically during the second time of the night, during the acute episode of depression (due to overactivity of GRH) and in the elderly (due to reduced activity of CHRH). These changes explain the aberrances of sleep endocrine activity in these states, as shallow sleep, low GH and enhanced cortisol.

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)

Sexually dimorphic effects of GHRH on sleep-endocrine activity in patients with depression and normal controls - part I: the sleep eeg.

In patients with depression, enhanced secretion of ACTH and cortisol, a reduction in slow wave sleep (SWS) and a blunted nocturnal growth hormone (GH) surge have been described and attributed, at least partly, to an elevation of corticotropin-releasing hormone (CRH), hence a shift in the ratio between growth hormone-releasing hormone (GHRH) and CRH. We investigated the effects of pulsatile administration of GHRH (4x50 microgram, at hourly intervals between 2200 and 0100 h) on the sleep EEG (2300-0700 h) in patients with depression (16 females, 19 males, age range 19-76 years) and matched controls (20 females, 20 males). In patients compared with controls, NREM sleep and in particular stage 2 sleep was greatly decreased at baseline. GHRH treatment enhanced NREM sleep, and in particular stage 2 sleep in men, regardless of diagnosis, while decreasing it in women (F=6.0 and 7.1, p<0.05). In controls, aging was associated with a decrease in NREM sleep, including both SWS and stage 2 sleep (r= -0.45 r= -0.39, p<0.05), while in patients only SWS declined with age (r= -0.49, p<0.05). The significant decrease in NREM sleep including stage 2 sleep in patients with depression and elderly control subjects is compatible with the suggested role of sleep continuity and stage 2 sleep in cognitive functioning. GHRH promoted NREM sleep, stage 2 sleep and sleep continuity and might prove beneficial for improvement of cognitive function, at least in men. These data support the hypothesis that female gender, aging and depression are associated with a shift in the GHRH/CRH ratio towards CRH.

Sexually dimorphic effects of GHRH on sleep-endocrine activity in patients with depression and normal controls - part II: hormone secretion.

In depression and aging an increase in nocturnal cortisol secretion and a blunted nocturnal growth hormone (GH) surge have been described. In normal young men, growth hormone-releasing hormone (GHRH) promotes GH release and reduces plasma cortisol. Here, we examined whether GHRH could help to restore sleep-endocrine regulation in patients with depression and aging. GHRH (4x50 microgram, at 2200, 2300, 2400 and 0100 h) or saline (placebo) was injected intravenously to 42 patients with depression (19 females, 23 males) and matched controls (age range 19-76 years). Blood samples were withdrawn at 20 min intervals between 2200-0700 h and analysed using Manova (D.F. 1, 72). Patients compared to controls had significantly higher levels of ACTH and cortisol, particularly during the first half of the night (F=9 and F=11.8, each p<0.05). GHRH reduced ACTH during the first and cortisol secretion during the second half of the night in males, regardless of diagnosis, but enhanced it in females (F=5.1 and F=4.0, each p<0.05). ACTH and cortisol secretion were inversely related to NREM and stage 2 sleep in patients (r= -0.42, -0.42 and r= -0.36, -0.39, respectively, each p<0.05) but not in controls. Our data suggest that: 1) female gender, depression and aging add-on to enhance HPA activity, and 2) hyperactivity of the HPA system and the decrease in NREM and in particular stage 2 sleep in depression are interrelated. In men, GHRH can restore some of the sleep-endocrine alterations associated with depression and aging.