EEG sleep in elderly depressed, demented, and healthy subjects

In a prospective study of EEG sleep patterns in 25 elderly depressives, 25 elderly demented patients, and 25 healthy, elderly control subjects, the sleep of depressives was characterized by reduced REM sleep latency, increased REM percent and first REM period density, and altered temporal distribution of REM sleep, as well as by diminished sleep maintenance (correlated significantly with Hamilton ratings of depression: multiple R = -0.42, p less than 0.05). In contrast, the sleep of demented patients showed reduced REM sleep percent, but normal REM temporal distribution, increased loss of spindles and K-complexes (the latter correlating significantly with severity of cognitive impairment as measured by the Folstein score: multiple R = -0.59, p less than 0.01), and less severe sleep maintenance difficulty than for depressives. An examination of REM latency demonstrated a skewed distribution in depression (i.e., 42% of nights with sleep-onset REM periods), but a normal distribution in the controls and demented subjects. A REM latency cut-off score of 30 min correctly classified 68% of all patients (kappa = 0.36; p less than 0.005), compared with 78% correctly identified in our retrospective study (Reynolds et al. 1983).     

Sleep stage transitions and tonic REM in depression

The hypothesis that greater perturbations of EEG-sleep architecture and continuity would occur in clinical depression contingent upon epsilon stage shifts was tested. Duration of successive REM cycles was also evaluated in 16 young adult (17-25 years) nonpsychotic unipolar patients with primary depression and eight age-matched normal controls for 8 hr during 1-3 consecutive EEG recording nights (epsilon N = 55). Two subgroups of eight patients were identified whose polysomnograms contained greater than 100 versus less than 100 epsilon sleep stage transitions. As predicted, sleep was shallow and fragmented to a significantly larger extent in depressives with: greater than 100 stage shifts versus, less than 100 transitions, compared with controls. This was reflected by significantly longer delays in falling asleep, more intermittent wakefulness transitions into stage 1, increased epsilon stage shifts, and more transitional stage 1 sleep. The depressed patients with less than 100 stage shifts (versus greater than 100 transitions relative to the controls) accumulated significantly less total sleep (7.0 vs greater than or equal to 7.6 hr), REM time; exhibited fewer REM episodes, and a slower REM cycle. Compared with controls both patient constituencies accumulated less REM time, showed a propensity for shallow NREM sleep reflected by significantly decreased stage 4, and more frequent transition into stage 1. REM time significantly increased progressively during sleep through the fourth cycle in both controls and depressives. The initial REM cycle was significantly longer among patients (N = 16), and the fourth proved to be shorter compared with controls. The longer first REM cycle in primary depression is construed to represent a disinhibition of neural processes that would normally either attenuate or delay this phenomenon. Accordingly, the possibility is raised that REM sleep disinhibition potentiates the mood disturbances and neurovegetative symptoms of endogenous/primary depression.     

Premorbid polysomnographic signs in depressed adolescents: a reanalysis of EEG sleep after longitudinal follow-up in adulthood.

BACKGROUND: This is a report of a clinical follow-up study (10-15 years later as young adults) of adolescent major depressives and normal control subjects. Polysomnographic data were obtained during the original study period when the subjects were adolescent (time 1). With clinical follow-up (time 2) assessments in hand, our objective was to ascertain whether there were any premorbid polysomnographic signs associated with depression during adolescence. METHODS: Based upon initial (during adolescence) and follow-up clinical assessments (as adults), new subject groupings were generated: depression-free normal subjects and original normal subjects who experienced a depressive episode during the follow-up period (latent depressives). Suicidality and recurrence of depression were also examined. Multivariate analysis of covariance was used to analyze group differences in sleep measures and logistic regression for predicting three outcomes: lifetime depression, lifetime suicidality, and recurrence. RESULTS: Comparison of the depression-free normal subjects, the latent depressives, and the original major depressives revealed significant differences for sleep latency and sleep period time. Comparing all lifetime depressives (original major depressives and the latent depressives) to depression-free normal subjects revealed significantly more stages 3 and 4 combined (ST34) sleep and greater sleep period times among the depressives. An analysis involving the presence or absence of suicidality revealed no overall significant differences between the groups. Comparison of the lifetime depressives grouped by nonrecurrent and recurrent depressive course to the depression-free normal subjects revealed significant difference for sleep period time. Using logistic regression, we found that a longer sleep latency and sleep period time significantly predicted lifetime depression. Gender, ST34 sleep, and an interaction term for ST34 sleep and REM latency significantly predicted lifetime suicidality. CONCLUSIONS: There was evidence of premorbid sleep abnormalities during adolescence. A general pattern of sleep disruption around sleep onset and during the first 100 min of the sleep period and overall sleep was evident among the major and lifetime depressives, involving sleep latency (initial insomnia), sleep period time (hypersomnia), REM latency, and slow-wave sleep. This adds to the body of literature that highlights the importance of the first 100 min of the sleep period in depression.     

Application of automated REM and slow wave sleep analysis: II. Testing the assumptions of the two-process model of sleep regulation in normal and depressed subjects

Abnormalities in a two-process model of sleep regulation (a sleep-dependent process, termed Process S, and a sleep-independent circadian process, termed Process C) have been proposed to account for sleep abnormalities in depressive states. The major tenets of the two-process model of sleep regulation as applied to depression are: the level of process S, as reflected by the electroencephalographic (EEG) slow-wave activity, corresponds to the sleep-dependent facet of sleep propensity; the pathognomonic changes of sleep in depressives are a consequence of a deficiency in the build-up of process S. The application of automated rapid eye movement (REM) and delta wave analyses in normal subjects and younger depressed patients supports the model to some extent: The time spent asleep is positively correlated with total delta waves (normals and depressives) and average delta waves (depressives); delta sleep is lower in depressives than in normals; the average delta wave count is significantly reduced in younger depressives over the total night and in non-REM period 1. The model also postulates that measures of phasic REM activity are inversely related to process S, suggesting that process S can be regarded as exerting an inhibitory influence on phasic REM activity.     

脑卒中后抑郁状态的多导睡眠图研究

目的：探讨脑卒中后抑郁状态患者的睡眠图异常改变及与抑郁症之间的差异。方法：采用多导睡眠图对６２例脑卒中和３０例抑郁症患者进行整夜睡眠描记，并与对照组比较。结果：卒中后抑郁组与对照组和非抑郁组比较多项睡眠指标均有显著性差异（Ｐ＜０．０５～０．０１）；卒中后抑郁组的ＲＥＭ睡眠时间和密度明显低于抑郁症组，差异有显著性（Ｐ＜０．０１）。结论：卒中后抑郁状态病人除具有睡眠障碍在多导睡眠图改变外，ＲＥＭ睡眠时间和密度是一个较为特征性的改变，卒中后抑郁状态的发生可能与脑内５－ＴＨ递质改变有关。     

Sleep in anorexia nervosa, bulimia nervosa and depressive diseases: a polysomnographic comparative study

All-night EEG sleep in 20 anorexics, 10 bulimics, 10 endogenous depressives, and in 10 healthy subjects (all age matched) was compared. In addition, the REM sleep-induction-test was performed in 12 patients with an eating disorder, 7 depressives, and 12 controls by application of the cholinergic agent RS 86. During baseline night, EEG-sleep parameters, especially REM latency, did not differ between the patients and the controls, except for the phasic components of REM sleep (REM density) that were increased in the depressive patients. The frequency of shortened REM latencies, however, was significantly higher in the depressed patients. These observations indicate that in some of the young depressives the disturbance of the REM sleep regulating transmitter system is already present to a similar degree as it is assumed in elderly depressives. After the application of RS 86, REM latency was shortened in all groups under investigation. However, the REM sleep inducing effect of RS 86 was significantly more pronounced in the depressives when compared with both the eating disorder patients and the controls. In the latter two samples, the shortening of REM latency was similar. Furthermore, the eating disorder patients with a concomitant major depression reacted similar to RS 86 as the non-depressed eating disorder patients and the control subjects. Whereas baseline EEG-sleep did not differ significantly among eating disorder patients, young depressives, and healthy subjects, the REM sleep inducing effect of the cholinergic agent RS 86 clearly distinguished between the depressives and both the patients suffering from eating disorders and the controls.(ABSTRACT TRUNCATED AT 250 WORDS)     

Electroencephalographic sleep in young, never-medicated schizophrenics. A comparison with delusional and nondelusional depressives and with healthy controls

Electroencephalographic (EEG) sleep characteristics of young, never-medicated, nonschizoaffective schizophrenics were compared with the EEG sleep of patients with major depressive disorders (delusional and nondelusional) and with that of healthy controls. Schizophrenics had decreased sleep continuity comparable to delusional depressives. Slow-wave sleep percent was similar to that seen in healthy controls, as was the intranight temporal distribution of EEG delta activity. However, schizophrenics showed diminished delta counts per minute of non-rapid eye movement (NREM) sleep and a decreased total delta wave count. In contrast, depressives showed diminished slow-wave sleep percent compared with controls, greatly decreased delta activity (more so than did the schizophrenics), and an altered temporal distribution of delta activity, as evidenced by a shift of delta activity from the first to the second NREM period. Minutes of slow-wave sleep in the schizophrenics was inversely correlated with the severity of negative symptoms independent of the effects of age and the presence of depression. The schizophrenics showed normal REM latency and first REM period duration, in contrast to the depressives. These findings, reviewed in the historical context of sleep physiologic studies of schizophrenia over the past 30 years, suggest that young, never-medicated schizophrenics do not show the characteristic constellation of abnormalities in the first NREM-REM cycle seen in patients with major depression. However, decreased slow-wave sleep should be investigated as a possible marker for negative symptoms in schizophrenia.     

The sleep EEG's microstructure in depression: alterations of the phase relations between EEG rhythms during REM and NREM sleep

OBJECTIVE: We investigated the microstructure of sleep electroencephalograms (EEGs) of 13 unmedicated depressive inpatients and 13 healthy controls matched in sex and age, hypothesizing that depressives depict an alteration of certain EEG oscillations across the night. METHODS: We digitized the sleep EEGs with a sampling rate of 100 Hz (bipolar derivation C(z)-P(z), 1440 single sweeps; 2048 data points each), calculated the time course of delta (1-3.5 Hz), theta (3.5-7.5 Hz), alpha (7.5-15 Hz), and beta (15-35 Hz) activity over the night, and determined the correlation coefficients of these different EEG rhythms separately for rapid eye movement (REM) and non-rapid eye movement (NREM) sleep. RESULTS: For both groups we detected a clear difference between REM and NREM sleep cycles at certain frequency bands. The most impressive changes occurred for the delta/beta and theta/beta correlations, which change their signs between NREM (negatively correlated) and REM (positively correlated) sleep cycles. Following an analysis of variance model with repeated measurement design, a statistically significant group effect (P=0.024) between depressives and controls was observable during NREM sleep for the delta/beta (P=0.010) and theta/beta (P=0.018) interactions. CONCLUSION: We detected alterations of certain sleep EEG oscillations during the NREM sleep cycle, where the delta/beta as well as the theta/beta activities were higher (negatively) compared to healthy controls. Together with previous investigations on the influence of antidepressants on the microstructure of sleep EEGs, this is another hint that the NREM sleep cycle plays a major role in depression.     

Cholinergic REM sleep induction in atypical depression

The arecoline REM induction test, a measurement of central cholinergic sensitivity, was performed in 10 patients with atypical depression. Arecoline induced REM sleep significantly more rapidly than placebo. Atypical depressives without evidence of anxiety, in particular those without panic attacks, had a more rapid REM induction response to arecoline than atypicals with anxiety symptoms. We compared our atypical depressives with normal controls and affectively ill patients studied in other laboratories. The rapid REM induction response observed in atypical depressives without anxiety was comparable to that seen in endogenous depressives and euthymic bipolars. Previous studies have demonstrated the presence of cholinergic supersensitivity in the latter two groups of patients. Our results suggest that atypical depressives may be distinguished in their response to arecoline based on their anxiety history, and that cholinergic supersensitivity is present in atypical depressives without anxiety. Additional studies with larger samples and simultaneously studied control groups are necessary to test these preliminary findings.     

REM latency in depression: is there one best definition?

The concurrent validity of different definitions of REM latency has been tested by comparing the ability of each definition to discriminate between primary depressives (outpatients and inpatients) and normal controls. In outpatients the percentage of cases correctly identified ranged from 62.5% to 70.8%; in inpatients, from 64.6% to 70.8%. REM latency definitions with the least stringent sleep-onset criteria yielded the lowest specificity. In contrast, the range of sensitivities yielded by different definitions was narrower and not clearly affected by sleep-onset criterion or exclusion/inclusion of wakefulness between sleep onset and first REM period. Furthermore, different definitions of REM latency correlated equally well (p less than 0.01) with Hamilton depression ratings. The shorter REM latencies in both outpatients and inpatients were associated with a later time of NREM sleep onset than in controls, rather than with an earlier REM sleep-onset time.     

抑郁症患者可乐定快速眼运动睡眠抑制试验的对照研究

目的探讨重性抑郁症患者α2-肾上腺能受体功能状况。方法对15例重性抑郁症患者（抑郁症组）和15名正常人（正常对照组）分别进行多导睡眠脑电图检查。在第1个快速眼运动（REM）睡眠周期结束10min内,向所有被试者静脉注射可乐定（剂量按2mg/kg体重计算,并稀释于9ml生理盐水中）,比较两组的睡眠情况。结果可乐定注射前,抑郁症组的REM比例［（26.8±5.6）%］、REM次数［（6.8±1.2）次］及REM时间［（120.6±25.1）min］较正常对照组增加［分别为（19.2±3.3）%、（4.9±0.8）次、（78.8±14.4）min;P<0.05］,REM潜伏期缩短［（64.1±27.0）min,对照组为（96.1±27.0）min］;可乐定注射后,对两组非快速眼运动睡眠几乎无影响,而抑郁症组和对照组的REM比例［分别为（21.3±4.8）%和（13.6±2.7）%］、次数［分别为（5.3±1.2）次和（3.8±0.6）次］、时间［（101.0±24.0）min和（61.0±10.3）min］分别较注射前减少（P<0.05）,抑郁症组第1次和第2次REM间隔时间的差值小于正常对照组（P<0.01）;而两组REM潜伏期注射前后的差异均无显著性。提示抑郁症患者REM睡眠的可乐定反映较正常对照组迟钝。结论重性抑郁症患者可能存在α2-肾上腺能受体功能低下。     

From early to late adulthood. Changes in EEG sleep of depressed patients and healthy volunteers

In order to evaluate the impact of aging on EEG sleep patterns we investigated the polysomnograms of 74 patients with major depression and 51 healthy volunteers aged 18-65 years. In most of the EEG sleep parameters, age-related changes were obvious in both the depressives and the normals. In the patients, some of these alterations occurred earlier and were more pronounced. The amount of slow-wave sleep decreased with age, but no differences were found between the depressives and the healthy volunteers at any particular age. Rapid-eye-movement (REM) latency was clearly affected by age, but there were no significant differences between patients and controls until the middle of the fourth decade of life. On the other hand, REM density measures did not vary with age and were increased in the depressives. Therefore, REM density appears to be a more likely candidate for a biologic marker for major depression than is REM latency.     

Comparison between eye movement latency and REM sleep parameters in major depression

Alterations of sleep can be observed polysomnographically in approximately 90 percent of depressed patients. Most of the registered sleep abnormalities in depression also occur in other psychiatric disorders. Only some types of REM sleep alterations – short REM latency, increase of REM density and shortening of mean latency of eye movements – were reported as more specific for affective disorders. In the present study polysomnograms of 21 medication free patients with major depressive disorder (assessed with a structured interview for DSM-III-R and Hamilton Scale) and 21 healthy controls were analysed. REM latency (LREM), REM density (RD), latencies of eye movements (LEM) and mean latency of eye movements (M-LEM) were calculated for both groups. Depressed patients (compared with healthy controls) showed increased RD (38.2% vs. 28.2%, p < 0.0001), shortened M-LEM (35.7 s vs. 48.3 s, p < 0.04) and shortening of LEM in the 1st (28.9 s vs. 48.9 s, p < 0.007) and 4th (27.0 s vs. 59.1 s, p < 0.043) REM sleep periods. LREM was not shortened significantly in depressives (78.5 min vs. 91.3 min, ns). In healthy subjects a negative correlation between M-LEM and RD was found (rho = − 0.47, p < 0.03). Since in the current study depressed patients differed from healthy controls, especially concerning phasic activity during REM sleep, presented data support the essential role of REM density for the assessment of sleep in depression. As a quick and easy manner to compute measurement, M-LEM is suggested as additional parameter for the assessment of phasic activity during REM sleep. Received: 23 March 1999 / Accepted: 23 November 1999     

EEG sleep in young depressives: first and second night effects

The sleep electroencephalogram (EEG) of young, drug-free, recurrently depressed outpatients was analyzed for 2 nights and was compared to age-matched controls using a variety of standard and computerized measures of sleep activity. On the first night, young depressives showed significantly greater difficulty in falling asleep and decreased sleep efficiency. Sleep architecture differences between the young depressives and controls were highlighted by increased percentages of Stage 2 sleep and major decreases in Stages 3 and 4 (delta wave) sleep among the depressives, as indicated by either period analyses or spectral analysis. The greatest differences in delta wave activity during night 1 were found in the first two (non-rapid eye movement (NREM) periods as measured by period analysis (NREM period 1, p less than 0.04; NREM period 2, p less than 0.001--average delta wave count) or by spectral analysis for the first 100 min of sleep (0.5-2.0 Hz). In contrast to the NREM sleep findings, various REM variables, including REM latency did not significantly distinguish the two subject groups for either night 1 or 2. Stepwise discriminant analysis demonstrated that night 1 sleep latency and delta wave counts during the second NREM period correctly classified 100% of all 16 individuals studied. The only differences between the young depressed patients and controls that remained on night 2 were significant reductions in slow-wave sleep as quantified by the computerized methods. Taken together, these findings suggest that the EEG response of young outpatients to the first night's stay in a sleep laboratory may be a useful tool for the diagnosis of depression in this age group. In addition, the use of computerized methods in this study point to an underlying deficit in delta sleep waveforms as being a prominent feature of the sleep of young depressed subjects.     

Sleep, depression, and suicide

In a retrospective study of the electroencephalographic (EEG) sleep of major depressives with and without a history of suicide attempts, suicide attempters had longer sleep latency, lower sleep efficiency, and fewer late-night delta wave counts than normal controls. Nonattempters, compared to attempters, had less rapid eye movement (REM) time and activity in period 2, but more delta wave counts in non-REM period 4. Although both attempters and nonattempters were like controls in regard to REM period 2, patients with suicide attempts had altered intranight temporal distribution of phasic REM activity, with increased REM activity (by both visual and automated scoring) in REM sleep period 2 (significant group x period interaction). These findings, which may be more traitlike or persistent than state-related, are discussed in the context of current theories on the role of serotonin in the regulation of sleep and in suicidal behavior.     

The cholinergic REM induction test with RS 86 after scopolamine pretreatment in healthy subjects.

A shortened latency of rapid eye movement (REM) sleep is one of the most stable biological abnormalities described in depressive patients. According to the reciprocal interaction model of non-REM and REM sleep regulation, REM sleep disinhibition at the beginning of the night in depression is a consequence of heightened central nervous system cholinergic transmitter activity in relation to aminergic transmitter activity. A recent study has indicated that muscarinic supersensitivity, rather than quantitatively enhanced cholinergic activity, may be the primary cause of REM sleep abnormalities in depression. The present study tested this hypothesis by treating healthy volunteers for 3 days with a cholinergic antagonist (scopolamine) in the morning, in an effort to induce muscarinic receptor supersensitivity. On the last day of scopolamine administration, RS 86, an orally active cholinergic agonist, was administered before bedtime to test whether this procedure would induce sleep onset REM periods. Whereas scopolamine treatment tended to advance REM sleep and to heighten REM density in healthy controls in comparison to NaCl administration, the additional cholinergic stimulation did not provoke further REM sleep disinhibition. This result underlines the need to take a hypofunction of aminergic transmitter systems into account in attempts to explain the pronounced advance of REM sleep typically seen in depressives.     

Reliable discrimination of elderly depressed and demented patients by electroencephalographic sleep data

Using electroencephalographic sleep data from a sample of 235 elderly subjects, discriminant function analyses of sleep alterations in depression and dementia were performed. Overall, 80% of patients were correctly classified using a backward discriminant function analysis, and 81% with a general stepwise discriminant function analysis. Four measures contributed to the separation of depressed and demented patients: rapid eye movement (REM) sleep latency (lower in depressives); REM sleep percent (higher in depressives); indeterminate non-REM sleep percent (higher in demented patients, reflecting greater loss of spindles and K complexes); and early morning awakening (more marked in depressives). When both discriminant functions were subjected to cross-validation in independent subsamples, both procedures correctly identified 78% of patients. The classification functions derived from nondemented depressed and nondepressed demented patients were applied to a mixed-symptom group (n = 42). Overall, 27 patients (64%) with either depressive pseudodementia or dementia with depressive features were correctly classified using the same four predictor variables. These findings suggest that sleep physiological alterations of depression and dementia reflect between-group differences in sleep continuity, sleep architecture, and REM sleep temporal distribution, and that the differences are statistically reliable, in both diagnostically pure and mixed clinical presentations. These findings are discussed in the context of current hypotheses of sleep regulation and its mechanisms.     

Sleep in depression: the influence of age,gender and diagnostic subtype on baseline sleep and the cholinergic REM induction test with RS 86

Summary One hundred and eight healthy controls and 178 patients with a major depressive disorder according to DSM-III were investigated in the sleep laboratory after a 7-day drug wash-out period. Subsamples of 36 healthy controls and 56 patients additionally took part in the cholinergic rapid eye movement (REM) sleep induction test with RS 86. Data analysis revealed that age exerted powerful influences on sleep in control subjects and depressed patients. Sleep efficiency and amount of slow wave sleep (SWS) decreased with age, whereas the number of awakenings, early morning awakening, and amounts of wake time and stage 1 increased with age. REM latency was negatively correlated with age only in the group of patients with a major depression. Statistical analysis revealed group differences for almost all parameters of sleep continuity with disturbed indices in the depressed group. Differences in SWS were not detected. REM latency and REM density were altered in depression compared to healthy subjects. Sex differences existed for the amounts of stage 1 and SWS. The cholinergic REM induction test resulted in a significantly more pronounced induction of REM sleep in depressed patients compared with healthy controls, provoking sleep onset REM periods as well in those depressed patients showing baseline REM latencies in the normal range. Depressed patients with or without melancholia (according to DSM-III) did not differ from each other, either concerning baseline sleep or with respect to the results of the cholinergic REM induction test. The results stress the importance of age when comparing sleep patterns of healthy controls with those of depressed patients. Furthermore they underline the usefulness of the cholinergic REM induction test for differentiating depressed patients from healthy controls and support the reciprocal interaction model of nonREM-REM regulation and the cholinergic-aminergic imbalance hypothesis of affective disorders.     

Polysomnography in patients with post‐traumatic stress disorder

Aims: The purpose of the present study was to investigate sleep structure in post‐traumatic stress disorder (PTSD) patients with and without any psychiatric comorbidities. The relationship between sleep variables and measurements of clinical symptom severity were also investigated. Methods: Sleep patterns of 24 non‐medicated male PTSD patients and 16 age‐ and sex‐matched normal controls were investigated on polysomnography on two consecutive nights. Six PTSD‐only patients and 15 PTSD patients with major depressive disorder (MDD) were also compared to normal controls. Sleep variables were correlated with PTSD symptoms. Results: Compared to the normal controls, the PTSD patients with MDD had difficulty initiating sleep, poor sleep efficiency, decreased total sleep time, decreased slow wave sleep (SWS), and a reduced rapid eye movement (REM) sleep latency. The PTSD patients without any comorbid psychiatric disorders had moderately significant disturbances of sleep continuity, and decreased SWS, but no abnormalities of REM sleep. REM sleep latency was inversely proportional to the severity of startle response. SWS was found to be inversely correlated with the severity of psychogenic amnesia. Conclusions: PTSD patients have disturbance of sleep continuity, and SWS deficit, without the impact of comorbid depression on sleep. The relationship between SWS and the inability to recall an important aspect of trauma may indicate the role of sleep in the consolidation of traumatic memories. The relationship between the severity of the startle response and REM latency may suggest that REM sleep physiology shares common substrates with the symptoms of PTSD.     

REM sleep and cortisol response to the cholinergic challenge with RS 86 in normals and depressives

The influence of the muscarinic agonist RS 86 on rapid-eye-movement (REM) sleep and on hypothalamic-pituitary-adrenocortical (HPA) axis was studied in healthy subjects and in patients with a major depression. In both groups, RS 86 induced a shortening of REM latency and an increase in REM sleep; these effects were more pronounced in the depressives than in the controls. This finding supports the assumption that in depression the REM sleep regulating neurons are hypersensitive to cholinergic stimuli. However, neither in the healthy subjects nor in the depressed patients was an RS 86 induced increase in plasma cortisol seen. This observation does not agree with the assumption that, in humans, the HPA axis is stimulated by muscarinic neurons and that hypercortisolemia in depression is due to an overactivity of muscarinic neurons activating the HPA axis.