Early rise in blood pressure following administration of adrenocorticotropic hormone-[1-24] in humans.

1. An elevation in blood pressure has been consistently observed 24 h after adrenocorticotropic hormone (ACTH) administration and is caused by increased ACTH-stimulated cortisol secretion, in association with increased cardiac output. The aim of the present study was to investigate the previously undefined time of onset of this increase in blood pressure in normal humans. 2. Ten normal healthy volunteers received 250 mg ACTH-[1-24], in 500 mL normal saline, infused at a constant rate over 8 h. Six subjects also received a placebo infusion (normal saline only). Blood pressure, heart rate and cortisol levels were determined hourly. Adrenocorticotropic hormone (ACTH-[1-24] plus native ACTH) was measured at 0, 1, 7 and 8 h. 3. Infusion of ACTH-[1-24] produced maximal secretion rates of cortisol, resulting in a mean peak plasma level of 985 +/- 46 nmol/L at 8 h. In response, blood pressure and heart rate rose significantly by 2 h and remained generally elevated for the duration of the infusion. 4. The early onset of haemodynamic responses is consistent with classical steroid receptor-mediated genomic mechanisms, but could be due non-genomic mechanisms. 5. The cardiovascular consequences of therapeutic use of ACTH are well recognized. This results of the present study suggest that even diagnostic administration of ACTH, delivered over a few hours, may raise blood pressure.

The insulin hypoglycemia test: hypoglycemic criteria and reproducibility.

The insulin hypoglycemia test (IHT) is widely regarded as the "gold standard" for dynamic stimulation of the hypothalamic-pituitary-adrenal (HPA) axis. This study aimed to investigate the temporal relationship between a rapid decrease in plasma glucose and the corresponding rise in plasma adenocorticotropic hormone (ACTH), and to assess the reproducibility of hormone responses to hypoglycemia in normal humans. Ten normal subjects underwent IHTs, using an insulin dose of 0.15 U/kg. Of these, eight had a second IHT (IHT2) and three went on to a third test (IHT3). Plasma ACTH and cortisol were measured at 15-min intervals and, additionally, in four IHT2s and the three IHT3s, ACTH was measured at 2.5- or 5-min intervals. Mean glucose nadirs and mean ACTH and cortisol responses were not significantly different between IHT1, IHT2 and IHT3. Combined data from all 21 tests showed the magnitude of the cortisol responses, but not the ACTH responses, correlated significantly with the depth and duration of hypoglycemia. All subjects achieved glucose concentrations of of < or = 1.6 mmol/l before any detectable rise in ACTH occurred. In the seven tests performed with frequent sampling, an ACTH rise never preceded the glucose nadir, but occurred at the nadir, or up to 15 min after. On repeat testing, peak ACTH levels varied markedly within individuals, whereas peak cortisol levels were more reproducible (mean coefficient of variation 7%). In conclusion, hypoglycemia of < or = 1.6 mmol/l was sufficient to cause stimulation of the HPA axis in all 21 IHTs conducted in normal subjects. Nonetheless, our data cannot reveal whether higher glucose nadirs would stimulate increased HPA axis activity in all subjects. Overall, the cortisol response to hypoglycemia is more reproducible than the ACTH response but, in an individual subject, the difference in peak cortisol between two IHTs may exceed 100 nmol/l.

Adrenocorticotropin stimulation tests in patients with hypothalamic-pituitary disease: low dose, standard high dose and 8-h infusion tests.

OBJECTIVES: Low doses of ACTH [1-24] (0.1, 0.5 and 1.0 microg per 1.73 m2) may provide a more physiological level of adrenal stimulation than the standard 250 microg test, but not all studies have concluded that the 1.0 microg is a more sensitive screening test for central hypoadrenalism. Eight-hour infusions of high dose ACTH [1-24] have also been suggested as a means of assessing the adrenals' capacity for sustained cortisol secretion. In this study, we compared the diagnostic accuracy of three low dose ACTH tests (LDTs) and the 8-h infusion with the standard 250 microg test (HDT) and the insulin hypoglycaemia test (IHT) in patients with hypothalamic-pituitary disease. SUBJECTS AND DESIGN: Three groups of subjects were studied. A healthy control group (group 1, n = 9) and 33 patients with known hypothalamic or pituitary disease who were divided into group 2 (n = 12, underwent IHT) and group 3 (n = 21, IHT contraindicated). Six different tests were performed: a standard IHT (0.15 U/kg soluble insulin); a 60-minute 250 microg HDT; three different LDTs using 0.1 microg, 0.5 microg and 1.0 microg (all per 1.73 m2); and an 8-h infusion test (250 microg ACTH [1-24] at a constant rate over 8 h). RESULTS: Nine out of the 12 patients in group 2 failed the IHT. Three out of 12 patients from group 2 who clearly passed the IHT, also passed all the ACTH [1-24] stimulation tests. Seven of the 9 patients who failed the IHT, failed by a clear margin (peak cortisol < 85% of the lowest normal). Two of the 7 also failed all the ACTH [1-24] tests. Five of the 7 patients had discordant results, four passed the 0.1 LDT, one (out of four) passed the 0.5 LDT, none (out of three) passed the 1.0 LDT, two passed the HDT and three passed the 8-h test. Two patients were regarded as borderline fails in the IHT. Both passed the ACTH [1-24] tests, although one was a borderline pass in the 8-h test. Only five out of the 21 patients in group 3 showed discordance between the HDT and the LDTs. One patient passed the HDT and failed the 0.1 LDT, four patients failed the HDT but passed some of the different LDTS. CONCLUSIONS: We conclude that in the diagnosis of central hypoadrenalism, ACTH [1-24] stimulation tests may give misleading results compared to the IHT. The use of low bolus doses of ACTH [1-24] (1.0, 0.5 or 0.1 microg) or a high dose prolonged infusion does not greatly improve the sensitivity of ACTH [1-24] testing. Dynamic tests that provide a central stimulus remain preferable in the assessment of patients with suspected ACTH deficiency.

Comparison of adrenocorticotropin (ACTH) stimulation tests and insulin hypoglycemia in normal humans: low dose, standard high dose, and 8-hour ACTH-(1-24) infusion tests.

The efficacy of the standard high dose ACTH stimulation test (HDT), using a pharmacological 250-microg dose of synthetic ACTH-(1-24), in the diagnosis of central hypoadrenalism is controversial. The insulin hypoglycemia test is widely regarded as the gold standard dynamic stimulation test of the hypothalamo-pituitary-adrenal (HPA) axis that provides the most reliable assessment of HPA axis integrity and reserve. Alternatively, a prolonged infusion of ACTH causes a continuing rise in plasma cortisol levels that may predict the adrenals' capacity to respond to severe ongoing stress. In nine normal subjects, we compared plasma ACTH and cortisol levels produced by three i.v. bolus low doses of ACTH-(1-24) (0.1, 0.5, and 1.0 microg/1.73 m2; LDTs) with those stimulated by hypoglycemia (0.15 U/kg insulin) and with the cortisol response to a standard 250-microg dose of ACTH-(1-24). The normal cortisol response to an 8-h ACTH-(1-24) infusion (250 microg at a constant rate over 8 h) was determined using three modern cortisol assays: a high pressure liquid chromatography method (HPLC), a fluorescence polarization immunoassay (FPIA), and a standard RIA. In the LDTs, stepwise increases in mean peak plasma ACTH were observed (12.4 +/- 2.0, 48.2 +/- 7.2, 120.2 +/- 15.5 pmol/L for the 0.1-, 0.5-, and 1.0-microg LDTs, respectively; P values all <0.0022 when comparing peak values between tests). The peak plasma ACTH level after insulin-induced hypoglycemia was significantly lower than that produced in the 1.0-microg LDT (69.6 +/- 9.3 vs. 120.2 +/- 15.5 pmol/L; P < 0.0002), but was higher than that obtained during the 0.5-microg LDT (69.6 +/- 9.3 vs. 48.2 +/- 7.2 pmol/L; P < 0.02). In the LDTs, statistically different, dose-dependent increases in peak cortisol concentration occurred (355 +/- 16, 432 +/- 13, and 482 +/- 23 nmol/L; greatest P value is 0.0283 for comparisons between all tests). The peak cortisol levels achieved during the LDTs were very different from those during the HDT (mean peak cortisol, 580 +/- 27 nmol/L; all P values <0.00009. However, the mean 30 min response in the 1.0-microg LDT did not differ from that in the HDT (471 +/- 22 vs. 492 +/- 22 nmol/L; P = 0.2). In the 8-h ACTH infusion test, plasma cortisol concentrations progressively increased, reaching peak levels much higher than those in the HDT [995 +/- 50 vs. 580 +/- 27 nmol/L (HPLC) and 1326 +/- 100 vs 759 +/- 31 nmol/L (FPIA)]. Significant differences in the basal, 1 h, and peak cortisol levels as determined by the three different assay methods (HPLC, FPIA, and RIA) were observed in the 8-h infusion tests. Similarly, in the HDTs there were significant differences in the mean 30 and 60 min cortisol levels as measured by HPLC compared with those determined by FPIA. We conclude that up to 30 min postinjection, 1.0 microg/1.73 m2 ACTH-(1-24) stimulates maximal adrenocortical secretion. Similar lower normal limits at 30 min may be applied in the 1.0-microg LDT and the HDT, but not when lower doses of ACTH-(1-24) are administered. The peak plasma ACTH level produced in the 1.0-microg LDT is higher than in the insulin hypoglycemia test, but is of the same order of magnitude. The peak cortisol concentration obtained during an 8-h synthetic ACTH-(1-24) infusion is considerably higher than that stimulated by a standard bolus 250-microg dose, potentially providing a means of evaluating the adrenocortical capacity to maintain maximal cortisol secretion. Appropriate interpretation of any of these tests of HPA axis function relies on the accurate determination of normal response ranges, which may vary significantly depending on the cortisol assay used.

Pituitary-adrenal responses to combined oral D-fenfluramine and intravenous naloxone in humans.

1. 1. Fenfluramine is an optically active 5-hydroxytryptamine (5-HT) releaser and re-uptake inhibitor. Increased brain 5-HT mediates appetite suppression, the D enantiomer being more active than L- or DL-fenfluramine. Fenfluramine also stimulates the hypothalamic-pituitary-adrenal (HPA) axis, leading to suggestions that this could act as a marker for its biological actions. However, the D enantiomer appears less active than a comparable DL racemate dose in animals, while effects of D-fenfluramine on the human HPA axis remain unproven. The aim of the present study was to clarify this. 2. Seven healthy human volunteers (three male, four female; 18-58 years) received 30 mg oral D-fenfluramine or placebo, followed by 125 micrograms/kg, i.v. naloxone or placebo, in randomized, double-blinded, placebo-controlled afternoon studies. We measured plasma adrenocorticotropic hormone (ACTH) and cortisol levels in samples taken at intervals throughout the study period. 3. In contrast to previous results with DL-fenfluramine, we found no dynamic responses to D-fenfluramine alone and no augmentation of responses to naloxone. 4. Central pathways to HPA axis activation are apparently not stimulated by D-fenfluramine at this dose in humans, in contrast with DL-fenfluramine, where the L enantiomer may be more selective for proposed corticotropin-releasing hormone-mediated, post-synaptic 5-HT2 or noradrenergic mechanisms. As previously reported, D-fenfluramine significantly blunted the circadian fall in basal plasma cortisol, providing in vivo evidence for serotonergic involvement in circadian regulation.

Inhibition of naloxone-stimulated adrenocorticotropin release by alprazolam in myotonic dystrophy patients.

Myotonic dystrophy (DM) is an autosomal dominant disorder causing myotonia, progressive muscle weakness, and endocrine abnormalities including hypothalamic-pituitary-adrenal (HPA) axis hyperresponsiveness to CRH-mediated stimuli. This ACTH hyperresponsiveness appears directly related to the underlying genetic abnormality. Naloxone (Nal)-mediated CRH release causes ACTH release in normal humans and an ACTH hyperresponse in DM. Alprazolam (APZ) attenuates the ACTH release in response to Nal in normal individuals, probably by inhibiting CRH release. This study investigates the effects of APZ on Nal-induced HPA axis stimulation in DM. The ACTH response to Nal in DM subjects was significantly reduced by APZ. Despite this DM patients have a relative resistance to APZ inhibition of Nal-induced ACTH/cortisol release. APZ caused a smaller percentage reduction in AUC for ACTH in DM compared with controls. These findings provide further insight into the mechanism(s) of the HPA axis abnormalities in DM. In DM, there may be an increase in tonic opioid inhibition to CRH release with compensatory increases in stimulatory pathways. Alternatively, these patients may have a basal increase in pituitary vasopressin levels or an enhanced AVP/CRH synergistic mechanism at the level of the corticotroph.

Diurnal effects of fluoxetine and naloxone on the human hypothalamic-pituitary-adrenal axis.

1. Central serotonergic pathways are hypothesized to be involved in the stimulation of hypothalamic adrenocorticotropic hormone (ACTH) secretagogue release by both circadian- and stress-induced mechanisms. We aimed to investigate this hypothesis by measuring the effect of the highly specific serotonin re-uptake inhibitor fluoxetine (FX) on ACTH and cortisol release in the morning and in the afternoon in humans, both by itself and in combination with the opioid antagonist naloxone (Nal). Naloxone causes ACTH release in humans by removing an endogenous inhibitory opioid tone on central noradrenergic pathways stimulatory to hypothalamic corticotropin-releasing hormone (CRH) secretion. Serotonergic agents may act directly or indirectly through these central noradrenergic pathways and, if so, would be expected to be additive to or synergistic with Nal in causing ACTH and cortisol release. 2. Oral FX (40 mg) was given at approximately 07.00 or 11.00 h, either alone or with intravenous Nal 3 h later, to normal human volunteers. Plasma ACTH and cortisol levels were measured for 5 h after FX dosing. 3. Fluoxetine produced a small but non-significant increase in Nal-stimulated ACTH and cortisol release in both morning and afternoon studies. Naloxone alone did not cause different ACTH and cortisol responses in the morning and afternoon. 4. These results suggest that serotonergic pathways are not major regulators of the hypothalamic-pituitary-adrenal axis in humans or that FX has counteracting acute inhibitory effects on the axis, such as inhibition of hypothalamic arginine vasopressin secretion, which has been demonstrated in chronic animal studies.

Aspirin inhibits vasopressin-induced hypothalamic-pituitary-adrenal activity in normal humans.

PGs influence ACTH secretion. However, their specific role in modulating the activity of the human hypothalamic-pituitary-adrenal (HPA) axis remains unclear. Acetylsalicylic acid (aspirin) inhibits the synthesis of PGs from arachidonic acid by blocking the cyclooxygenase pathway. In this study we administered a single, clinically relevant dose of aspirin before HPA axis stimulation by a bolus dose of iv arginine vasopressin (AVP) to seven normal males using a randomized, placebo-controlled, single blinded design. Aspirin significantly reduced the cortisol response to AVP [mean peak increase from basal, 221.1 +/- 20.1 vs. 165.4 +/- 22.5 nmol/L (P = 0.0456); mean integrated response, 11,199.3 +/- 1,560.0 vs. 6,162.3 +/- 1,398.6 nmol.min/L (P = 0.0116) for placebo aspirin/AVP and aspirin/ AVP, respectively]. The ACTH response was reduced, but did not reach statistical significance [mean peak increase from basal, 7.5 +/- 2.2 vs. 4.3 +/- 0.3 pmol/L (P = 0.0563); mean integrated response, 142.6 +/- 36.0 vs. 96.2 +/- 8.7 pmol.min/L (P = 0.12) for placebo aspirin/ AVP and aspirin/AVP, respectively]. PGs may influence ACTH secretion by being stimulatory or inhibitory to the HPA axis at different levels, such as hypothalamic or pituitary. Which effect predominates in vivo during dynamic activation of the axis may depend on the level at which the secretory stimulus acts. We showed that when normal male volunteers were treated with the PG synthesis inhibitor, aspirin, they had a blunted HPA axis response to the pituitary corticotroph stimulator, AVP.

New diagnostic tests for Cushing's syndrome: uses of naloxone, vasopressin and alprazolam.

1. We set out to investigate whether the administration of naloxone alone, naloxone plus vasopressin (AVP) or naloxone plus alprazolam to patients with Cushing's syndrome would result in a blunted dynamic response of the pituitary-adrenal axis compared with normal volunteers. Cushing's syndrome is often difficult to diagnose. It would be helpful if new tests were available to help in the biochemical distinction between Cushing's syndrome and non-Cushing's syndrome patients. 2. Naloxone testing correctly distinguished all seven patients with Cushing's syndrome (four pituitary Cushing's, two adrenal adenomas, one ectopic ACTH) from normal. Six patients were distinguished by the per cent change of plasma ACTH from basal being less than the normal range of 10 volunteers. The seventh patient (a pituitary Cushing's) was distinguished by the per cent change from basal of plasma cortisol being less than the normal range. 3. Naloxone plus AVP testing of two of four patients with pituitary Cushing's showed a smaller per cent change for both ACTH and cortisol compared with five normal volunteers, correctly distinguishing Cushing's from the normals. 4. Naloxone plus alprazolam did not distinguish Cushing's from normal. 5. Naloxone testing and naloxone plus AVP testing appear to be promising methods of distinguishing Cushing's syndrome from normal. Further experience with these tests, especially with obese and pseudo-Cushing's individuals, will be necessary to determine their place in the diagnosis and differential diagnosis of the cause of Cushing's syndrome.

Infant luminance and chromatic contrast sensitivity: optokinetic nystagmus data on 3-month-olds.

Infant color vision is poor, and most psychophysical experiments agree that infant color vision emerges between ages 3 weeks and 3 months. Presumably, the color vision of infants is poor during the months immediately after it has emerged. We have tested two alternative explanations for the poor color vision of infants: (1) there is a special critical immaturity within the color pathways of infants; (2) infants have poor infant color vision because they are insensitive to contrast. Luminance and chromatic contrast thresholds were measured on 3-month-olds using optokinetic nystagmus (OKN), and adult luminance and chromatic contrast thresholds were measured using OKN and two forced-choice methods: direction-of-motion discrimination and grating detection. The infant chromatic-to-luminance contrast threshold ratio shows that infants are as sensitive or even more sensitive than adults to color, depending on the testing method used on adults. This result suggests that the general contrast insensitivity hypothesis is correct. Conservative "worst-case" quantitative analysis strongly suggests that this result is not the consequence of a luminance artifact.

Effect of sodium valproate on naloxone-stimulated ACTH and cortisol release in humans.

1. Gamma-aminobutyric acid (GABA) and endogenous opioids each inhibit hypothalamic CRH secretion. In humans, the opioid antagonist, naloxone, stimulates the release of CRH, and so of ACTH and cortisol, while alprazolam, an indirect GABAA agonist, blocks naloxone-induced ACTH and cortisol secretion. Sodium valproate (SV) inhibits ACTH release in response to CRH, metyrapone and substance P. We hypothesized that, if this action is GABAA-mediated, SV should also inhibit naloxone-stimulated ACTH release. 2. We studied five healthy volunteers in randomized, double-blind, placebo-controlled afternoon studies with SV 400 mg, given 180 min before i.v. naloxone 125 micrograms/kg bodyweight. Plasma concentrations of ACTH, cortisol and SV were measured at intervals during the experiments. 3. SV had no effect on the mean integrated ACTH and cortisol responses to naloxone; ACTH: 165 +/- 21 versus 284 +/- 40 pmol.min per L, P = 0.08; cortisol: 10.5 +/- 1.9 versus 12.8 +/- 1.2 nmol.min per L-3, P = 0.14, placebo/nal versus SV/nal respectively. Basal ACTH and cortisol levels were also not significantly altered by SV (P > 0.30). Mean SV levels were not significantly different between SV/nal and SV/placebo studies (P > 0.50). 4. In conclusion, SV had no effect on naloxone-induced ACTH and cortisol release in normal humans at the dose and plasma drug concentrations studied. This contrasts with the potent inhibitory effect of alprazolam, and suggests that the effect of SV on the human hypothalamic-pituitary-adrenal axis may not be through a GABAA-mediated mechanism. Alternatively, higher plasma SV levels or more sustained exposure to SV may be necessary to inhibit hypothalamic secretion of CRH.

The effect of desipramine on basal and naloxone-stimulated cortisol secretion in humans: interaction of two drugs acting on noradrenergic control of adrenocorticotropin secretion.

Desipramine (DMI), a tricyclic antidepressant and norepinephrine (NE) reuptake blocker, is reported to induce ACTH and cortisol release acutely in humans, probably by facilitating central NE neurotransmission. Tricyclic antidepressant therapy, including DMI, normalizes the ACTH and cortisol hypersecretion that often accompanies depression. The mechanism of hypothalamic-pituitary-adrenal (HPA) axis inhibition by DMI in humans is unknown. In rats, DMI reduces the activity of the locus ceruleus, a major source of NE innervation of the hypothalamic paraventricular nucleus, the site of CRH neurons. Naloxone induces ACTH and cortisol release in humans through a noradrenergic-mediated mechanism and a probable consequent stimulation of hypothalamic CRH release. To study the interaction of these drugs on NE neurotransmission and, hence, HPA axis activity in humans, we administered DMI alone and with naloxone in a randomized, double blind, placebo-controlled protocol in eight healthy male volunteers. DMI (75 mg, orally) was given 180 min before naloxone (125 micrograms/kg BW, i.v.). Plasma ACTH and cortisol were measured at frequent intervals from 60 min before to 120 min after naloxone treatment. Plasma cortisol levels were 77% higher 180 min after DMI compared to those after placebo treatment (287 +/- 17 vs. 162 +/- 14 nmol/L; P = 0.000005). DMI reduced the naloxone-induced rise in cortisol (P = 0.02), but there was no change in the integrated cortisol response. The increase in basal plasma ACTH levels after DMI treatment did not reach statistical significance. DMI significantly increased systolic blood pressure and heart rate consistent with an effect on the noradrenergic control of the cardiovascular system. In summary, DMI increased basal cortisol levels consistent with facilitation of NE neurotransmission and, hence, hypothalamic CRH release. However, DMI had no enhancing effect on naloxone-induced cortisol release. This contrasts with the synergy observed when non-antidepressant agents that increase NE neurotransmission are given with naloxone to humans. DMI increases glucocorticoid feedback sensitivity in the rat HPA axis after several weeks through up-regulation of central corticosteroid receptors. However, this slowly developing effect is unlikely to occur during these acute studies. The effect of DMI on naloxone-induced cortisol release is consistent with an inhibitory effect on central noradrenergic control of ACTH release, perhaps at the locus ceruleus. This is the first human study to suggest an inhibitory effect of DMI on central noradrenergic control of ACTH release.

A synergistic adrenocorticotropin response to naloxone and vasopressin in normal humans: evidence that naloxone stimulates endogenous corticotropin-releasing hormone.

Naloxone stimulates pituitary-adrenal function by blocking an endogenous inhibitory opioidergic tone which modulates pituitary adrenocorticotropin (ACTH) release. In animals, this action of naloxone is mediated by increased corticotropin-releasing hormone (CRH) secretion, but such a mechanism is disputed in humans. CRH and arginine vasopressin (AVP) are known to have a synergistic effect on ACTH secretion in both humans and animals. In vitro, this synergism is independent of L-type voltage-dependent Ca2+ channel function. The aims of this study were therefore: (i) to determine if the combined administration of naloxone and AVP is synergistic regarding ACTH release; (ii) to assess the effect of nifedipine, which blocks L-type Ca2+ channels, on the ACTH response to combined naloxone/AVP stimulation. Seven healthy volunteers were studied using a placebo-controlled, single-blind protocol. Naloxone (125 micrograms/kg) and/or AVP (10 units) were given in all four possible combinations, and oral nifedipine (20 mg) was also given with naloxone and AVP as an additional test. The mean AUC and the mean peak change in ACTH levels following combined naloxone/AVP administration were both significantly greater than the arithmetic sum of the ACTH responses to naloxone and AVP given on separate occasions (AUC: 1,576.4 +/- 417.9 vs. 567.1 +/- 106.1 pmol.min.l-1, p < 0.002; peak change: 37.9 +/- 14.0 vs. 11.8 +/- 2.0 pmol/l, p < 0.007). Nifedipine reduced the ACTH response to combined naloxone/AVP stimulation by 43% (AUC: 1,576.4 +/- 417.9 vs. 897.0 +/- 186.2; p < 0.05), but it remained greater than the sum of the individual responses (897.0 +/- 186.2 vs. 576.1 +/- 106.1, p < 0.05).(ABSTRACT TRUNCATED AT 250 WORDS)

Adrenocorticotropin hyperresponse to the corticotropin-releasing hormone-mediated stimulus of naloxone in patients with myotonic dystrophy.

We previously showed that CRH-mediated stimuli, including exogenous CRH, cause ACTH hypersecretion in many myotonic dystrophy (DM) patients. We confirmed this by giving naloxone, a stimulator of endogenous CRH release, to a large number of DM patients and controls. DM patients, first degree relatives, and normal controls received i.v. naloxone at 1400 h, and blood was taken for ACTH (RIA) and cortisol (high pressure liquid chromatography) measurements from 15 min before to 120 min after naloxone treatment. DM patients had basal ACTH levels approximately twice those of controls, and their ACTH responses were 4 times those of controls. In contrast, DM basal cortisol levels were not significantly different from those of relatives and were slightly higher than those of normal subjects. Cortisol responses were similar in the three groups, probably due to attenuation at high levels of adrenocortical stimulation, although some patients with inappropriately low cortisol responses for their level of ACTH stimulation warrant further investigation. Nineteen of the 36 patients whose ACTH responses were greater than 3 SD above the normal mean were classed as hyperresponders. Seven patients, who were tested more than once, had reproducible responses relative to those of the normal subjects. We conclude that ACTH hypersecretion after CRH-mediated stimuli, including naloxone, is an inherent, but variable, feature of DM, caused by expression of the genetic mutation at the anterior pituitary. The mechanism is probably a defect in the intracellular pathway initiated by CRH-receptor interaction as a result of abnormal levels of a cAMP-dependent kinase, DMPK, the product of the gene undergoing mutation in DM.

Alprazolam attenuates vasopressin-stimulated adrenocorticotropin and cortisol release: evidence for synergy between vasopressin and corticotropin-releasing hormone in humans.

Alprazolam (APZ), a triazolobenzodiazepine with unique clinical utility, has potent inhibitory effects on the human hypothalamic-pituitary-adrenal axis. Because APZ inhibits CRH secretion from isolated rat hypothalami and inhibits the probable CRH-mediated effect of naloxone on ACTH release, it is likely APZ acts as an inhibitor of hypothalamic CRH release in humans. The two principal physiological ACTH secretagogues are CRH and arginine vasopressin (AVP). We studied the ACTH and cortisol responses to an ACTH-releasing dose of AVP with and without preadministration of APZ in humans. Our hypothesis was that acute CRH deprivation by APZ would attenuate the ACTH response to vasopressin, as CRH and AVP act synergistically to control ACTH release. This synergy may depend on activation of subpopulations of corticotropes, some of which require both CRH and AVP together to elicit an ACTH response and/or intracellular "cross-talk" between second messenger pathways stimulated by the secretagogues. APZ (2 mg, orally) was given to eight healthy volunteers 90 min before AVP (0.0143 IU/kg BW, iv) in a randomized, double blind, placebo-controlled design during afternoon studies. ACTH and cortisol levels were measured at frequent intervals from 60 min before to 120 min after AVP injection. APZ reduced the mean integrated ACTH and cortisol responses to AVP by 67% and 70% respectively [ACTH, 161.6 +/- 59.7 vs. 53.0 +/- 20.9 pmol/min.L (P = 0.022); cortisol, 9314 +/- 3310 vs. 2763 +/- 1472 nmol/min.L (P = 0.020, AVP vs. APZ/AVP, respectively)]. APZ reduced the mean peak ACTH and cortisol responses to AVP by 57% (P = 0.023) and 40% (P = 0.0012), respectively. AVP levels were not significantly different in those who received APZ or placebo. This study provides further evidence of the potent inhibitory effects of APZ on ACTH and cortisol release in humans and is the first to find that APZ inhibits AVP-stimulated ACTH and cortisol release. This study also suggests that CRH/AVP synergy is an important physiological mechanism for ACTH release in humans, as indicated by the blunted ACTH response to AVP after APZ-mediated acute CRH deprivation. Inhibition of the pituitary-adrenal axis by APZ may explain its unique efficacy in psychiatric disorders thought to be associated with dysregulation of hypothalamic CRH release.

Paradoxical inhibition by aspirin of naloxone-induced adrenocorticotropin secretion in myotonic dystrophy.

The ACTH response to endogenous or exogenous CRH is increased in patients with myotonic dystrophy (DM), possibly because of abnormal function of cAMP-dependent protein kinases in this condition. Arachidonic acid (AA) metabolites are believed to interact with the cAMP-dependent second messenger system activated by CRH; therefore, drugs that interfere with AA metabolism may alter ACTH secretion in DM. In this study, seven DM patients were given naloxone, which stimulates endogenous CRH release, and aspirin, which inhibits the synthesis of prostaglandins from AA via the cyclooxygenase metabolic pathway. Pretreatment with aspirin reduced the mean integrated ACTH response to naloxone by 33% (P < 0.05). However, the corresponding 18% reduction in cortisol levels was not statistically significant (P > 0.10). These findings are in contrast to those of a previous study using an identical protocol, in which aspirin increased the ACTH response to naloxone in six normal volunteers. This difference between DM and control subjects is consistent with the hypothesis that the interaction between AA metabolites and the cAMP-dependent protein kinase-A second messenger system is abnormal in the corticotrophs of persons with DM.

Effect of flumazenil on basal and naloxone-stimulated ACTH and cortisol release in humans.

1. Endogenous benzodiazepine receptor ligands are thought to influence the human hypothalamic-pituitary-adrenal (HPA) axis and naloxone, a known stimulator of adrenocorticotropic hormone (ACTH) release, is thought to act via release of hypothalamic corticotropin-releasing hormone. 2. The aim of the present study was to assess the influence of endogenous benzodiazepine-receptor ligands by administering flumazenil (Ro15-1788), a benzodiazepine antagonist, and measuring ACTH and cortisol release, both basal and during naloxone-stimulation. 3. Nine normal volunteers in a placebo-controlled double-blind design were studied. Flumazenil (0.5 mg, i.v. bolus) was given 2 min before naloxone (125 micrograms/kg bodyweight, i.v. bolus) immunoreactive-adrenocorticotropic hormone (IR-ACTH) and cortisol levels were measured at frequent intervals from 60 min before to 120 min after naloxone injection. 4. Flumazenil had no effect on ACTH and cortisol release when given alone; flumazenil area under the ACTH/time curve (pmol/L.min) = -36.5 +/- 63.5 compared with placebo = -53.5 +/- 31.8, flumazenil area under the cortisol/time curve (nmol/L.min x 10(-3)) = - 2.4 +/- 2.4 compared with placebo -0.56 +/- 1.4. Flumazenil did not change the ACTH and cortisol release achieved with naloxone; naloxone area under the ACTH/time curve (pmol/L.min) = 327.8 +/- 61.7 compared with flumazenil/naloxone = 366.3 +/- 88.1, naloxone area under the cortisol/time curve (nmol/L. min x 10(-3) = 12.2 +/- 3.4 compared with naloxone/flumazenil = 10.5 +/- 2.1. 5. The authors conclude that flumazenil dose not modify basal or stimulated ACTH and cortisol release in healthy humans. This would suggest that endogenous benzodiazepine-like ligands and the benzodiazepine/gamma-aminobutyric acid receptor complex do not tonically influence the hypothalamic-pituitary-adrenal axis.

A comparison of large-scale Sf9 insect cell growth and protein production: stirred vessel vs. airlift.

A simple and relatively inexpensive stirred-vessel system for the large-scale growth of insect cells (Sf9) is described. Sf9 cell growth in a stirred-vessel fermentor and an airlift fermentor were compared on the basis of maximum cell density and average population doubling time. Also, both fermentor systems were compared with respect to the large-scale production of a recombinant human protein (protein kinase C-eta). No significant differences in Sf9 cell growth or protein expression levels were apparent between the two fermentor systems. However, large differences in cost and scale-up of each system are discussed with respect to the large-scale production of recombinant proteins.

Aspirin increases the human hypothalamic-pituitary-adrenal axis response to naloxone stimulation.

Prostaglandins are believed to influence hypothalamic-pituitary-adrenal (HPA) axis function, but their specific effects on ACTH and cortisol secretion in humans are unclear. Acetylsalicylic acid (aspirin) blocks the synthesis of prostaglandins from arachidonic acid. We studied the effects of oral aspirin on the plasma ACTH and cortisol responses to iv naloxone, which increases endogenous CRH release, in six normal volunteers and on the adrenocortical response to synthetic ACTH boluses in seven other healthy subjects, using placebo-controlled, single blinded protocols. Aspirin pretreatment significantly increased the ACTH response to naloxone [mean peak increase from basal, 8.3 +/- 1.2 vs. 5.9 +/- 0.8 pmol/L (P < 0.05); mean integrated response, 431.9 +/- 51.5 vs. 295.1 +/- 26.6 pmol/L.min (P < 0.005); for aspirin/naloxone and placebo aspirin/naloxone, respectively]. However, the corresponding cortisol results did not show statistically significant differences (P < 0.20). The mean integrated ACTH and cortisol responses were 46% and 26% greater with aspirin, respectively. Aspirin did not influence the cortisol responses to synthetic ACTH administration given according to a dose-response protocol. We conclude that aspirin augments the HPA axis response to naloxone stimulation in normal humans without having a direct effect at the adrenal level. The action of aspirin on the human HPA axis is probably mediated via inhibition of cyclooxygenase, resulting in changes in arachidonic acid metabolites, which influence ACTH release from corticotrophs.

Altered hypothalamic-pituitary-adrenal axis responsiveness in myotonic dystrophy: in vivo evidence for abnormal dihydropyridine-insensitive calcium transport.

In persons with myotonic dystrophy (DM), the ACTH response to CRH is greater than normal, while it is delayed in response to arginine vasopressin. Since influx of extracellular Ca2+ ions is a common step in signal transduction by both of these secretagogues, an abnormality of cellular Ca2+ transport may underlie the disturbances of hypothalamic-pituitary-adrenal axis function in this condition. Seven myotonic patients were given naloxone, which stimulates endogenous CRH release, and nifedipine, which blocks L-type voltage-dependent Ca2+ channels. Each subject underwent three tests, using different drug combinations, in a single blind, placebo-controlled protocol. Pretreatment with nifedipine delayed the time of the peak plasma hormone responses after naloxone [ACTH, 32.1 +/- 2.1 vs. 51.4 +/- 4.5 min (P < 0.05); cortisol, 42.9 +/- 2.1 vs. 70.7 +/- 4.3 min (P < 0.02); for naloxone and nifedipine/naloxone, respectively]. Additionally, nifedipine significantly reduced the proportion of the mean integrated ACTH response that had occurred by 30 min after naloxone administration (32.0 +/- 4.0% for naloxone vs. 17.6 +/- 2.4% for nifedipine/naloxone; P < 0.02) and the proportion of the mean integrated cortisol response by 45 min after naloxone administration (34.7 +/- 3.5% for naloxone vs. 25.0 +/- 2.6% for nifedipine/naloxone; P < 0.02). However, the total integrated responses did not change [ACTH, 1182.6 +/- 548.9 vs. 905.5 +/- 157.0 pmol/min.L (P = NS); cortisol 17,353 +/- 2,984 vs. 18,469 +/- 3,561 nmol/min.L (P = NS); for naloxone and nifedipine/naloxone, respectively]. We conclude that nifedipine delays, but does not reduce, the ACTH and cortisol responses to naloxone in DM. Since nifedipine has a different effect on normal controls (reduced response with unchanged timing), these findings imply an abnormality of dihydropyridine-insensitive Ca2+ transport (such as T-type Ca2+ channels) in the corticotrophs of DM patients.