Serum postdexamethasone prolactin measures in depressive patients and control subjects

Recently, some researchers noted significant positive relationships between postdexamethasone serum cortisol and prolactin levels, whilst endogenous depressives exhibited a significantly lower suppression of prolactin by dexamethasone than non-endogenous patients or normal controls. To ascertain the extent of prolactin responses to dexamethasone in severely depressed patients, we measured 8 a.m. pre- and postdexamethasone prolactin levels in 104 depressed and 42 normal subjects. Serum cortisol levels were also determined in depressed patients before and after dexamethasone administration. We found a significant suppressive effect of dexamethasone on prolactin levels. There were no significant differences either in pre- or postdexamethasone prolactin, or in actual dexamethasone-induced decrements in prolactin between normal controls, melancholics, simple major or minor depressed subjects. We have not found any significant relationships between cortisol and prolactin, either under baseline or postdexamethasone conditions.     

Cortisol, ACTH, prolactin and beta-endorphin responses to fenfluramine administration in major-depressed patients

In the past, some researchers found increased cortisol and prolactin responses to the administration of fenfluramine in major-depressed patients. It was believed that the fenfluramine test could prove to constitute another challenge probe to reflect the central serotonergic function. The present study was conducted in order to investigate the pituitary/adrenal responses to fenfluramine in major- versus minor-depressed patients. To this end we administered 60 mg D,L-fenfluramine p.o. to 40 depressed patients categorized according to the DSM-III. The basal levels of cortisol, adrenocorticotrophic hormone (ACTH), beta-endorphins and prolactin and their levels 2 and 4 h after fenfluramine administration were measured. We found no significant effect for fenfluramine treatment on cortisol, ACTH or beta-endorphins. There was a significant (p = 0.02) effect for fenfluramine treatment on prolactin. The enhanced secretion of prolactin was only significant (p = 0.006) in major (296.X2, 296.X3, 296.X4) and not in minor (300.40, 309.00) depressives. It was concluded that our findings corroborate the thesis of a hypersensitive serotonergic neurotransmission during a major depressive episode.     

Plasma levels of beta-endorphin, cortisol, prolactin and growth hormone in depressed patients

Basal serum cortisol, growth hormone, prolactin and immunoreactive (IR) plasma beta-endorphin levels were measured in 31 depressed patients (14 endogenous, 17 nonendogenous) undergoing the dexamethasone suppression test. The endogenously depressed patients had significantly higher (22.55 +/- 1.34 micrograms/dl) predexamethasone cortisol levels than the nonendogenous patients (16.34 +/- 1.93 micrograms/dl). The mean serum prolactin and growth hormone values of these two groups were not significantly different, while plasma IR-beta-endorphin levels of the endogenous group (40.11 +/- 3.57 pg/ml) were significantly lower than those of the nonendogenous group (120.33 +/- 27.98 pg/ml). Neither group showed a significant correlation between plasma IR-beta-endorphin and serum cortisol values. These results indicate that measurement of predexamethasone serum cortisol values and plasma IR-beta-endorphin could be valuable laboratory tests in the diagnosis of depression.     

Sex-linked differences in cortisol, ACTH and prolactin responses to 5-hydroxy-tryptophan in healthy controls and minor and major depressed patients

Some researchers have found that the administration of 5-hydroxytryptophan (5-HTP) results in increased cortisol secretion in major depressives but not in healthy controls. Other authors observed gender-related differences in cortisol responses to 5-HTP in major depressives. In order to investigate the pituitary/adrenal responsivity to 5-HTP, the authors measured cortisol, adrenocorticotropic hormone (ACTH) and prolactin (PRL) in 30 healthy controls and in 90 depressed patients; the hormone levels were determined in baseline conditions and 60, 90 and 120 min after 125 mg L-5-HTP (orally, non-enteric coated). We found that healthy men had significantly higher cortisol responses to L-5-HTP than healthy women. In the major depressives with melancholia and/or psychotic features these differences were reversed: women exhibited significantly higher cortisol and PRL responses than men. In the female group the most severely depressed patients had increased cortisol and PRL responses to L-5-HTP. The amplitudes of the cortisol, ACTH and PRL responses to L-5-HTP were significantly and positively correlated. It was concluded that the central serotonergic regulation of ACTH and PRL is significantly different between the sexes and between healthy controls, minor depressives and severely depressed patients.     

Postdexamethasone prolactin and cortisol: a biological state variable in depression

In 70 inpatients with major depressive disorder postdexamethasone cortisol and prolactin, but not baseline cortisol and prolactin, was found to correlate significantly with various state variables of depression. Postdexamethasone prolactin appeared to be a more specific state variable of depression compared with postdexamethasone cortisol. While prolactin was decreased following dexamethasone in controls and nonendogenous depressed patients, in endogenous depressed patients prolactin was increased by 30%. Due to this inverse prolactin response to dexamethasone, the sensitivity of this test should be considerably increased by using a higher dexamethasone dosage. The DST failed to be a diagnostic marker for any subgroup of depression.     

Hormone responses to fenfluramine and placebo challenge in endogenous depression.

Plasma prolactin and cortisol levels after oral administration of d-l fenfluramine hydrochloride (60 mg) and placebo were examined in 24 endogenously depressed patients and 21 age- and sex-matched normal control subjects in a randomized, double-blind study. Prolactin levels were significantly increased by fenfluramine in both groups, but the response was significantly blunted in the depressed patients compared with the controls. This effect was partially dependent upon elevated baseline cortisol levels in the depressed group and was also influenced by a history of weight loss. Plasma cortisol levels were not increased by fenfluramine in either group. These findings confirm previous reports and suggest that patients with endogenous major depression are characterized by central serotonergic hyporesponsivity. The need to account for baseline effects on hormonal responses to putative serotonergic agents is supported by the findings; however, these effects appear to be less striking when endogenicity is a prominent clinical feature of the depressive syndrome. The apparently complex influence of weight loss on prolactin response to serotonergic challenge remains to be clarified as well as the role played by the bioavailability of the challenge drug and its metabolite.     

TRH-induced prolactin release in unipolar depressed patients and controls

We compared unipolar depressed patients (N = 32) with normal controls (N = 38) for their prolactin responses on the thyrotropin releasing hormone test. Depressed patients showed prolactin responses similar to sex matched controls. Among the depressed patients there were no significant differences for prolactin response between those with or without a blunted thyroid stimulating hormone response, dexamethasone suppressors or nonsuppressors, or between melancholic and nonmelancholic depressive subgroups.     

Thyrotropin and prolactin responses to different doses of thyrotropin-releasing hormone in depression

The effects of low doses of thyrotropin-releasing hormone (TRH, 50 and 200 micrograms) on thyrotropin (TSH) and prolactin levels have been studied in depressed women and compared with the depressive condition and with the results of the dexamethasone suppression test (DST). TRH administration elicited blunted hormonal responses that were not correlated either with the age of the patients or with DST results. Different effects were observed in subgroups of depressive patients classified according to DSM III and ICD. No correlation was found between hormone responses and the scores of Hamilton Rating Scale and Montgomery Depression Scale. The effects of 50 micrograms on TSH were significant and inversely correlated with Anxiety Rating Scale scores. No dose-response effect was apparent of prolactin and TSH in depressed patients, suggesting an impaired function of pituitary TRH receptors.     

Effects of sertraline treatment on plasma cortisol, prolactin and thyroid hormones in female depressed patients

The aim of the study was to evaluate the effects of 4 and 24 weeks of sertraline treatment (average dose 42.5 mg/day) on plasma hormone levels in 15 female patients with major depression. Baseline levels of triiodothyronine (T(3)) were lower, while cortisol, prolactin (PRL), thyroid-stimulating hormone (TSH), and thyroxin (T(4)) levels did not differ from the values in 16 female controls. There was a positive correlation between the scores on the Montgomery-Asperg Depression Rating Scale and baseline cortisol levels. Treatment with sertraline for 4 weeks increased plasma cortisol levels, while 24 weeks of sertraline treatment increased plasma T(3) levels in depressed patients. Neither 4, nor 24 weeks of sertraline treatment affected PRL, T(4) and TSH levels in depressed patients. The data show different and time-dependent effects of sertraline treatment on plasma cortisol, PRL and thyroid hormones in female depressed patients.     

Abnormal neuroendocrine responsivity to acute i.v. clomipramine challenge in depressed patients

The neuroendocrine responsivity to an acute serotonergic challenge with low-dose i.v. clomipramine was studied in seven drug-free depressed patients and seven age-matched healthy control subjects. The depressed patients had higher baseline prolactin concentrations than the healthy subjects, and their prolactin response to clomipramine, assessed as either the percent of baseline or the log-transformed concentration, was significantly different (delayed and blunted peak response) compared to healthy controls. The growth hormone response was exaggerated in the depressed patients, and there were also trends toward blunting in their cortisol and adrenocorticotropic hormone responses. These results are consistent with previous findings of altered neuroendocrine responses to a variety of putative serotonin agonists in depressed patients.     

Thyroid hormones and TSH, prolactin and LH responses to repeated TRH and LRH injections in depressed patients.

Twelve patients with unipolar depressive disorders received 600 microgram of synthetic TRH or LRH, in a random order, for 3 days each. Placebo injections were given as two 3-day courses prior to and between the active treatments. Serum TSH, prolactin (Prl) and LH were measured by radioimmunoassays prior to the experiment as well as immediately before and 20 min after each injection. Serum T4 and T3 were determined by radioimmunoassays before the treatments and 24 h after the first two TRH injections. Serum T4 level in depressed patients did not differ from controls. Serum T3 level in depressed patients was significantly below, and the reverse T3 level was slightly above the normal mean. However, the latter difference was not statistically significant due to the large variation of rT3 levels among the depressed patients. The TSH responses did not differ from that of controls after the first injection but the responses after the second injection were lower than in a control study. The Prl responses to TRH were sub-normal in seven out of eight patients. Blunted LH responses to LRH were seen in three patients.     

Growth hormone and other hormonal responses to clonidine in melancholic and nonmelancholic depressed subjects and controls.

To study putative differences in central neurotransmitter function in depressive subtypes, growth hormone, adrenocorticotropic hormone (ACTH), cortisol, and prolactin responses to the alpha 2-noradrenergic receptor agonist clonidine (1.3 micrograms/kg i.v.) were examined in 26 subjects with major depression, 13 of whom had melancholia. The responses of 10 of these endogenous/melancholic subjects were compared with those of 10 controls who were matched to the patients on age, sex, and menopausal status. In 15 of the depressed subjects, prolactin and cortisol responses to the putative serotonergic agonist fenfluramine were also examined to test for associations between these challenges. There were no significant differences in any of the responses between melancholic and nonmelancholic depressive subgroups after controlling for age and sex. With the exception of a greater reduction in ACTH in the endogenous/melancholic subjects, there were also no significant differences in hormonal responses between these patients and controls. There was, however, a significantly greater reduction in systolic blood pressure in the control subjects. There were no significant correlations between the responses to clonidine and fenfluramine. The findings suggest that clonidine at a dosage of 1.3 micrograms/kg is neither able to differentiate reliably between depressive subtypes nor to differentiate reliably between depressed and control subjects.     

Neuroendocrine responses to intravenous tryptophan in major depression

The increases in plasma levels of prolactin (PRL) and growth hormone (GH) following intravenous administration of the 5-hydroxytryptamine precursor tryptophan (100 mg/kg) were assessed in 30 depressed patients and 30 control subjects. In depressed patients who lost less than 10 lb, PRL responses were significantly reduced compared with controls. In contrast, the PRL responses of patients with weight loss exceeding 10 lb were significantly greater than those of either controls or the other depressed patients. Growth hormone responses to tryptophan were significantly decreased in patients who lost less than 10 lb. Prolactin, but not GH, responses correlated significantly with the postdexamethasone plasma cortisol concentration; however, an apparent relationship between GH and PRL responses and suicidal behavior was probably due to the common factor of weight loss. The results suggest that depressed patients have different types of abnormal 5-hydroxytryptamine-mediated neuroendocrine responses that correlate with the presence or absence of severe weight loss and cortisol hypersecretion. Further investigations are needed to establish if these abnormalities are central to the depressive disorder or have implications for treatment response.     

HPA-Axis hormones and prolactin responses to dextro-fenfluramine in depressed patients and healthy controls

1. Like other authors we have established disturbances in central serotonergic neurotransmission in severely depressed patients by implementing hypothalamic pituitary adrenal (HPA)-axis hormones and prolactin responses to serotonin agonists or precursors.

2. Challenge probes with D,L fenfluramine have yielded controversial results. This substance, however, is not as serotonin-selective as previously believed.

3. Dextro(D)-fenfluramine, the dextrorotatory isomer of fenfluramine, constitutes a specific and potent serotonergic agonist.

4. In the present study the authors determined the following in healthy volunteers, and in depressed inpatients: the adrenocorticotropic hormone (ACTH), B endorphin, prolactin and cortisol responses to D-fenfluramine administration (45 mg orally), total L-tryptophan and the 8 a.m. postdexamethasone cortisol values.

5. We found no significant differences in any of the post-D-fenfluramine hormone levels across healthy controls, minor, simple major and melancholic depressives. There were no significant correlations between L-tryptophan or postdexamethasone cortisol on the one hand, and any of the post-D-fenfluramine hormone values on the other.     

Measurement of ACTH and prolactin in the dexamethasone suppression test

Plasma concentrations of ACTH and prolactin were measured in psychiatric inpatients at 8 a.m. and 4 p.m. before and after the standard 1 mg overnight Dexamethasone Suppression Test (DST). Plasma concentrations of cortisol were measured at 8 a.m. and 4 p.m., and 11 p.m. before and after 1 mg dexamethasone. Dexamethasone suppressed plasma concentrations of ACTH, prolactin and cortisol in the subject group as a whole. "Cut Points" obtained using Fisher's Exact Test identified plasma ACTH values at 8 a.m. baseline, 4 p.m. baseline and 8 a.m. post-dexamethasone and plasma prolactin values at all four times that significantly differentiated patients with bipolar depressive disorder and major depressive disorder from other psychiatric patients. There were no cut points found at any of the six times for plasma levels of cortisol that significantly differentiated between these two diagnostic groups. Of interest in this subject population, basal (pre-dexamethasone) plasma concentrations were of more diagnostic information than post-dexamethasone values. These pilot findings suggest that monitoring plasma prolactin and ACTH concentrations before and after dexamethasone might increase the sensitivity and specificity of this laboratory test for depression.     

24-h Monitoring of plasma norepinephrine, MHPG, cortisol, growth hormone and prolactin in depression

Depression is associated with alterations in hormone and catecholamine circadian rhythms. Analysis of these alterations has the potential to distinguish between three neurobiological models of depression, the catecholamine model, the phase advance model and the dysregulation model. Although a number of studies of 24-h rhythms have been reported, inconsistencies among the findings have complicated efforts to model the chronobiology of depression. The present study takes advantage of frequent plasma sampling over the 24-h period and a multioscillator cosinor model to fit the 24-h rhythms. METHOD: Plasma levels of norepinephrine, cortisol, prolacatin and growth hormone were sampled at 30-min intervals, and MHPG at 60-min intervals, over a 24-h period in 22 patients with major depressive disorder and 20 healthy control volunteers. RESULTS: The depressed patients had phase advanced circadian rhythms for cortisol, norepinephrine and MHPG, phase advanced hemicircadian rhythms for cortisol and prolactin, and a phase advanced ultradian rhythm for prolactin compared to healthy control subjects. In addition, the rhythm-corrected 24-h mean value (mesor) of norepinephrine was lower in the depressed patients compared to the healthy controls. There also was a poorer goodness-of-fit for norepinephrine to the circadian oscillator in the depressed patients relative to the healthy controls. CONCLUSIONS: These findings provide partial support for the dysregulation model of depression and are consistent with those studies that have found phase advances in cortisol, norepinephrine and MHPG rhythms in depression.     

Thyroid axis activity and serotonin function in major depressive episode.

Recent studies in depression have reported alterations in both hypothalamic-pituitary-thyroid (HPT) axis activity and serotonin (5-HT) function; however, the functional relationships between the two systems have not been well defined in patients with major depressive episode. Thyrotropin (TSH) response to 0800 and 2300 h protirelin (TRH) challenges, and adrenocorticotropic hormone (ACTH), cortisol, and prolactin (PRL) responses to D-fenfluramine (D-FEN), a specific 5-HT releasing/uptake-inhibiting agent, were examined in 60 drug-free DSM-IV major depressed inpatients and 20 hospitalized controls. Compared with controls, patients showed lower basal serum 2300 h TSH, 2300 h maximum increment in serum TSH above baseline (delta TSH) and difference between 2300 h delta TSH and 0800 h delta TSH (delta delta TSH) levels. The hormonal responses to D-FEN (i.e. delta ACTH, delta cortisol and delta PRL) were interrelated. No significant difference in basal and post-D-FEN ACTH, cortisol or PRL values were found between controls and patients. A negative relationship between hormonal responses to D-FEN and 2300 h delta TSH and delta delta TSH values was observed in the depressed group. When patients were classified on the basis of their delta TSH test status, patients with reduced delta delta TSH values (i.e. with HPT axis abnormality) had hormonal D-FEN responses comparable to those of controls. Patients with normal delta delta TSH values (i.e. without HPT axis abnormality) showed lower ACTH, cortisol and PRL responses to D-FEN than controls and patients with abnormal delta delta TSH values. These results suggest that: (1) pathophysiological mechanisms other than 5-HT dysregulation may be involved in TSH blunting in major depressed patients; (2) 5-HT function is reduced in some depressed patients, especially those without HPT axis abnormality; and (3) HPT dysregulation may be regarded as a compensatory mechanism for diminished central 5-HT activity.     

Neuroendocrinological investigations during sleep deprivation in depression. II. Longitudinal measurement of thyrotropin, TH, cortisol, prolactin, GH, and LH during sleep and sleep deprivation

Thyrotropin (TSH), thyroxin (T4), triiodothyronine (T3), free T3 (fT3), cortisol, prolactin, and human growth hormone (HGH) were measured every 2 hr during a night of sleep, the following day, and a night of sleep deprivation (SD) in 14 patients with major depressive disorder. In subgroups fT4 (n = 5), reverse T3 (rT3), and luteinizing hormone (LH) (n = 6) were also investigated. Significant increases in TSH, T4, fT4, T3, fT3, rT3, and cortisol and decreases in prolactin levels occurred during the night of SD, compared to the pattern during the night of sleep. The pre-SD T4 and T3 levels of the responders to SD were already higher than in the nonresponders, and increased less during SD. The cortisol and HGH concentrations of the responders rose higher during SD than those of the nonresponders. Changes in TSH and prolactin were not correlated to clinical response. Analysis of possible neurochemical mechanisms underlying this "pattern" of changes in different endocrine profiles suggests that enhanced noradrenergic activity might play a role in the changes in TSH, cortisol, thyroid hormones, and possibly HGH secretion during SD, and increased dopaminergic tone probably induced the decline in prolactin levels. Additional effects of the serotonergic system cannot be excluded at present. In conclusion, the data suggest that enhanced noradrenergic activity of the locus coeruleus stimulates alpha and/or beta adrenergic receptors in depressed patients during SD. This mechanism could well be involved in the antidepressant effect of this therapy.     

Growth hormone (GH) and prolactin responses after GH-releasing hormone in major depressive disorder: relationship to somatomedin C levels and dexamethasone suppressibility of cortisol

To explore the growth hormone-releasing hormone (GHRH)-GH-somatomedin axis in major depressive disorder, 12 patients and 12 normal controls matched to the patients on age, sex, ovarian status and body weight received synthetic human GHRH-44 amide (1 microgram/kg) as an intravenous bolus. Compared to controls, the depressed patients showed a reduction in baseline plasma GH and a significant attenuation of net plasma GH responses to GHRH. The blunted GH responses occurred along with significantly increased somatomedin C (Sm-C) concentrations. The impairment of GH responses to GHRH and the increased Sm-C concentrations in patients with depression could have resulted from episodic hypersecretion of GH during the daytime, indicating integrity of the negative feedback circuitry. Normal feedback regulation suggests that diurnal episodic hypersecretion of GH reflects an abnormality at or above the level of the hypothalamus, so that the GHRH-GH-somatomedin axis hyperactivity observed in certain patients with major depressive disorder may be due, at least in part, to hypersecretion of hypothalamic GHRH. Our failure to demonstrate a difference in plasma prolactin (PRL) responses to GHRH between controls and depressed patients indicates that GHRH is not a PRL releaser in patients with major depression and that the altered GH secretory dynamics may not be directly related to the altered circadian PRL secretion linked to depression.     

精神分裂症患者神经内分泌激发试验对照研究

目的：以帕罗西汀为探针探讨首发精神分裂症的中枢5-羟色胺(5-HT)系统的功能。方法：患者组为首发精神分裂症患者24例；另选择年龄、性别相匹配的15名正常人为对照组。口服40mg帕罗西汀作为激发剂，每隔1．5h连续抽取静脉血，共5次。使用酶联免疫吸附法测定血浆皮质醇及催乳素浓度。结果：试验前患者组血浆基础催乳素及皮质醇浓度显著高于对照组，激发试验后患者组2种激素浓度显著高于基础值及对照组；而帕罗西汀对正常人催乳素、皮质醇的释放增加不明显。结论：首发精神分裂症患者中枢5-HT功能可能亢进。