Effects of ovine corticotropin-releasing hormone on adrenocorticotropin secretion in the absence of glucocorticoid feedback inhibition in man.

We studied 1) the nature of the plasma ACTH response to ovine CRH (oCRH) in the absence of normal glucocorticoid negative feedback inhibition and 2) the cause of the diminished circadian peak in plasma ACTH in normal men the morning after 3-30 micrograms/kg BW doses of oCRH. Placebo or oCRH (3 micrograms/kg BW, iv) was administered as iv injections to five normal men given metyrapone to produce acute glucocorticoid deficiency. Four studies were performed: 1) placebo oCRH plus placebo hydrocortisone (HC), 2) oCRH plus placebo HC, 3) placebo oCRH plus HC, and 4) oCRH plus HC. HC was given as a variable rate iv infusion to mimic the plasma cortisol response to the same dose of oCRH in normal men. Plasma cortisol levels rose only slightly after oCRH, indicating nearly complete blockade of cortisol biosynthesis. Plasma cortisol levels during the HC infusion were similar to those in normal men given 3 micrograms/kg oCRH. There was an exaggerated rise in both the first and second peaks of the plasma ACTH response to oCRH in the metyrapone-treated men. HC infusion did not alter the plasma ACTH response during the first 60 min after oCRH, but markedly attenuated the response thereafter; however, it did not affect the timing of the second peak. This inhibitory effect continued for up to 11 h, which was 2-3 h longer than the period that plasma cortisol levels were increased. Thus, cortisol secreted in response to ACTH released by oCRH modulates, after about a 60-min delay, the continuing release of ACTH. Despite the greater oCRH-induced release of pituitary ACTH in the metyrapone-treated men, the magnitude of their next morning's circadian plasma ACTH peak was similar to that after they received placebo oCRH. Thus, depletion of pituitary ACTH did not appear to explain the diminished circadian peak. Its magnitude was reduced by the combination of oCRH and HC, but not by HC alone. Administration of oCRH, alone or in combination with HC, delayed the onset of the circadian rise, while oCRH, HC, or the combination thereof delayed the time of the circadian peak. Thus, it appears that both the glucocorticoid response to oCRH and direct or indirect effect(s) of oCRH are required to produce these two phenomena.

ENDO-LAB: an integrated, portable endocrinology laboratory software system.

ENDO-LAB is an IBM PC-based system which performs calculations and record-keeping for the Vanderbilt University Medical Center Endocrinology Laboratory. It manages maintenance and quality control, and prints reports for regulatory agencies. The system was designed to minimize paperwork without changing laboratory procedures in any way. Key features of ENDO-LAB include a uniform user interface, and error detection mechanisms. The system is designed to detect data which has been incorrectly entered. In addition, where the efficacy of a test can be determined on the basis of limited data, preliminary graphs are screened as soon as possible, so that the user can terminate lengthy calculations whose outcome would be invalid or inconclusive. ENDO-LAB is an integrated system in that the same statistical and calibration programs can be applied to all of the analyses. The system is both extensible and portable; it has been successfully implemented outside Vanderbilt.

Increased pro-opiomelanocortin-derived peptide release in myotonic dystrophy.

The response of plasma immunoreactive (IR)-ACTH, IR-beta-endorphin (beta-END) and IR-cortisol to insulin-induced hypoglycaemia, an acute stimulus to the pituitary corticotrophs through the central nervous system, and to synthetic ovine corticotrophin-releasing hormone (CRH), a direct corticotroph stimulator, were studied in normal males and males with myotonic dystrophy. Myotonics had an increased IR-ACTH and IR-beta-END response to hypoglycaemia and an increased IR-ACTH response to CRH compared with normals. Plasma IR-cortisol response were not different in either group of subjects to both stimuli. This neuroendocrine abnormality in myotonic dystrophy may represent a manifestation of the purported specific cell membrane defect underlying the disease. This is the first report of an abnormality in proopiomelanocortin peptide release in myotonic dystrophy.

Effect of altered thyroid hormone levels on hypothalamic-pituitary-adrenal function.

To determine whether alterations in serum thyroid hormone levels affect hypothalamic-pituitary-adrenal function, we measured the plasma immunoreactive (IR) ACTH and IR-cortisol responses to 1 microgram/kg BW ovine CRH (oCRH) given iv in the late afternoon and the plasma IR-ACTH, IR-cortisol, and IR-11-deoxycortisol responses to 2 g metyrapone given orally at midnight in 10 athyreotic patients during T4 treatment and 1 month after stopping T4 when they were biochemically, but not clinically, hypothyroid. Mean serum TSH increased from 0.7 +/- 0.9 (+/- SD) mU/L (normal range 0.5-4.9 mU/L) during T4 therapy to 107 +/- 82 mU/L after stopping T4. The serum total T4 level and free T4 index fell from 165 +/- 37 nmol/L and 1.9 +/- 0.4, respectively (normal range, 59-154 nmol/L and 0.9-2.5, respectively), to 19 +/- 9 and 0.2 +/- 0.1, respectively, after stopping T4. Basal plasma IR-ACTH and IR-cortisol levels at 0800 and 1630 h were similar during and after stopping T4 therapy. Peak plasma IR-ACTH and IR-cortisol levels after oCRH were significantly greater after stopping T4 (20 +/- 9.2 pmol/L and 880 +/- 260 nmol/L, respectively) than during T4 therapy (9.7 +/- 4.7 pmol/L and 720 +/- 190 nmol/L; P less than 0.01 and P less than 0.05, respectively). The mean integrated plasma IR-ACTH and IR-cortisol responses to oCRH were also significantly greater P less than 0.01 and P less than 0.05, respectively) after stopping T4 than during T4 therapy. Plasma IR-ACTH the morning after metyrapone was slightly (1.6-fold) but not significantly greater during therapy than after stopping T4 therapy (100 +/- 86 vs. 65 +/- 54 pmol/L, respectively). The plasma IR-11-deoxycortisol responses to metyrapone during and after stopping T4 therapy were similar (720 +/- 250 and 750 +/- 330 nmol/L, respectively), presumably because plasma IR-ACTH concentrations were maximally stimulating in both instances. These results indicate that thyroid hormone deficiency of short duration 1) increases corticotroph sensitivity to oCRH, 2) may diminish the plasma ACTH response to metyrapone-induced hypocortisolemia, and 3) has no apparent effect on the acute adrenal response to ACTH. These data together with those of previous studies that have shown reduced responses of the hypothalamic-pituitary-adrenal axis to metyrapone and hypoglycemia in hypothyroid patients suggest that the release of hypothalamic CRH and/or other ACTH secretagogues may be decreased in hypothyroidism.

Effect of ovine corticotropin-releasing hormone administered during insulin-induced hypoglycemia on plasma adrenocorticotropin and cortisol.

The factors that mediate the hypothalamic-pituitary response to hypoglycemia in man are unknown. To investigate the role of CRH in the plasma ACTH response to hypoglycemia, two different doses of ovine CRH (oCRH) were given to normal men during insulin-induced hypoglycemia. We hypothesized that if the endogenous CRH response to hypoglycemia were less than maximally stimulating, administration of oCRH during hypoglycemia would result in a greater peak plasma immunoreactive (IR) ACTH response. Six normal men were given 1) 0.15 U/kg regular insulin, iv; 2) insulin plus 1 microgram/kg oCRH, iv, 5 min after serum glucose fell to 40 mg/dL or less; and 3) oCRH alone. The degree and duration of hypoglycemia were the same when insulin was given alone or with oCRH. Plasma IR-ACTH after insulin alone and insulin plus oCRH rose at the same rate to similar peaks of 226 +/- 37 (mean +/- SEM) and 213 +/- 53 pg/mL, respectively, both of which were greater (P less than 0.05) than the peak plasma IR-ACTH after oCRH alone (61 +/- 19 pg/mL). The peak plasma IR-cortisol levels after insulin alone (24 +/- 4 micrograms/dL), insulin plus oCRH (27 +/- 3 micrograms/dL), and oCRH alone (18 +/- 2 micrograms/dL) were not significantly different. In a second study, six normal men were given 0.15 U/kg regular insulin, iv; insulin plus 10 micrograms/kg oCRH, iv; and 10 micrograms/kg oCRH alone. Administration of oCRH 5 min after serum glucose fell to 40 mg/dL or less did not affect the degree or duration of hypoglycemia. Plasma IR-ACTH after insulin alone and insulin plus oCRH rose at the same rate to similar peaks of 258 +/- 14 and 290 +/- 33 pg/mL, respectively, both of which were greater (P less than 0.01) than the peak (54 +/- 6 pg/mL) after oCRH alone. After insulin alone, plasma IR-ACTH declined to baseline by 3 h. However, after insulin plus oCRH, plasma IR-ACTH fell gradually until 2 h, rose to a second peak at 2.5-3 h, and remained greater (P less than 0.01) than after insulin or oCRH alone for the 4-h duration of the study. The mean peak plasma IR-cortisol level after insulin plus oCRH (33 +/- 4 micrograms/dL) was similar to that after insulin alone (28 +/- 3 micrograms/dL), but was greater (P less than 0.05) than that after oCRH alone (18 +/- 2 micrograms/dL).(ABSTRACT TRUNCATED AT 400 WORDS)

Gonadotropins and testosterone escape from suppression during prolonged luteinizing hormone-releasing hormone antagonist administration in normal men.

The ability of prolonged administration of a LHRH antagonist, [Ac-delta 3Pro1,4F-D-Phe2,D-Trp3,6]LHRH (4F-antagonist), to suppress serum gonadotropin and testosterone levels was studied in normal men. The 4F-antagonist was given either as a continuous 13.3 micrograms/kg X h sc infusion for 72 h or as intermittent sc injections of 100 micrograms/kg every 6 h for 7 days. Serum FSH, LH, and testosterone levels decreased in the period immediately following initiation of 4F-antagonist administration. However, an escape toward baseline levels for each of these hormones occurred during prolonged antagonist administration. When men receiving the continuous infusion were challenged with iv bolus doses of 50 micrograms LHRH, the response of LH after the first 12 h of 4F-antagonist administration was similar to that before its administration. This gonadotropin and testosterone escape suggests that, at the doses used, the inhibitory action of the antagonist on gonadotropin secretion is progressively lost. The initial decrease in androgen levels could serve to augment endogenous LHRH release, which, in turn, overcomes the pituitary effects of the antagonist, or to augment endogenous LH secretion directly. These results demonstrate that the pituitary can escape from the suppressive effects of prolonged LHRH antagonist administration and partially restore serum gonadotropin and testosterone levels to normal in man.

Suppression of pituitary-gonadal function by a potent new luteinizing hormone-releasing hormone antagonist in normal men.

LHRH antagonists compete with endogenous LHRH for binding to receptors on pituitary gonadotrophs and thereby inhibit gonadal function by suppressing gonadotropin secretion. We studied the effects of a recently developed LHRH antagonist on the pituitary-gonadal axis in man. The antagonist Detirelix [( N-Ac-D-Nal(2)1, D-pCl-Phe2,D-Trp3, D-hArg(Et2)6, D-Ala10]LHRH) was given as a single sc injection to nine normal men at three dose levels (5, 10, and 20 mg) at intervals of at least 7 days. Serum FSH, LH, and testosterone levels were measured before treatment, at frequent intervals for 48 h, and 72, 96, and 168 h after administration of the antagonist. Mean serum FSH levels decreased (P less than 0.001) from 6.9 +/- 0.5 (+/- SEM) mIU/mL to nadirs of 4.4 +/- 1.1, 3.6 +/- 0.9, and 4.1 +/- 0.9 after the 5-, 10-, and 20-mg doses, respectively. Serum LH levels decreased (P less than 0.001) from 6.2 +/- 0.3 mIU/mL to nadirs of 3.3 +/- 0.4, 2.8 +/- 0.3, and 2.7 +/- 0.3 after all three doses. Serum testosterone levels decreased (P less than 0.001) in a dose-dependent fashion from 5.1 +/- 0.2 ng/mL to nadirs of 1.3 +/- 0.3, 0.9 +/- 0.3, and 0.6 +/- 0.1 after the same doses. After the initial testosterone decrease, however, escape occurred 12-28 h after the lower doses. The area under the response curve, describing hormone concentrations as a function of time during the study, diminished by 23 +/- 2%, 36 +/- 4%, and 36 +/- 3% for FSH, by 14 +/- 6%, 30% +/- 6%, and 34 +/- 5% for LH, and by 41 +/- 5%, 58 +/- 6%, and 68 +/- 4% for testosterone with the same doses, respectively. The apparent plasma disappearance half-life of Detirelix by RIA was at least 41 h after all three doses. Detirelix elicited only a minor local reaction; no systemic side-effects were observed within the dose range used. These results indicate that this LHRH antagonist is a safe, highly potent inhibitor of the human pituitary-gonadal axis with an exceptionally long duration of action.

Corticotropin-releasing hormone: stimulation of ACTH secretion in normal man.

Synthetic ovine corticotropin-releasing hormone (oCRH) is a potent and specific ACTH secretagogue in man. Threshold and maximal i.v. doses are 0.01-0.03 and 3-10 micrograms/kg or less, but increase in frequency, severity, and duration at higher doses. oCRH produces a biphasic plasma immunoreactive (IR)-ACTH response and has a prolonged duration of action that is probably due to its long circulating half-life. Other pro-opiomelanocortin IR-peptide are secreted concomitantly in equimolar amounts. Plasma IR-cortisol concentration tends to follow that of ACTH, but also reflects cortisol's longer circulating half-life and the fact that acutely the maximally-stimulating plasma IR-ACTH level is about 45 pg/ml. oCRH is as effective given s.c. as i.v., but intranasal administration is only 1% as effective. Sex and age have no effect on the plasma IR-ACTH and IR-cortisol responses to oCRH. The time of day of oCRH administration has little influence on the plasma IR-ACTH response, but the plasma IR-cortisol response is much greater to oCRH given later in the day than early in the morning. Plasma IR-ACTH response to oCRH is more dependent on the basal plasma IR-cortisol level than the time of day. Arginine vasopressin given at the same time as oCRH potentiates 4-fold the plasma IR-ACTH response to oCRH alone, almost to levels obtained with insulin-induced hypoglycemia. However, oCRH administered at the onset of insulin-induced hypoglycemia does not cause higher plasma IR-ACTH levels, indicating that endogenous CRH levels are maximally-stimulating during the hypoglycemic response.(ABSTRACT TRUNCATED AT 250 WORDS)

Influence of yohimbine on release of anterior pituitary hormones.

We used a double-blind crossover design to study the effects of alpha 2 adrenoreceptor blockade with yohimbine on levels of anterior pituitary hormones. A dose of yohimbine was used which raised plasma norepinephrine from 379 +/- 74 (S.E.) to 730 +/- 143 pg/ml and mean arterial pressure from 83 +/- 4 to 92 +/- 5 torr (p less than 0.025). This dose (125 micrograms/kg, then 1 microgram/kg/min) also altered mood when compared to saline infusion. In spite of these changes, when prolactin, cortisol, ACTH, beta-endorphin, TSH and growth hormone were measured after 45 minutes of yohimbine infusion, no changes from baseline were noted. These data suggest that in normal man, at rest, alpha 2 adrenoreceptors in the hypothalamus, adenohypophysis or other brain areas do not tonically modulate release of these hormones into the blood.

Single subcutaneous doses of a luteinizing hormone-releasing hormone antagonist suppress serum gonadotropin and testosterone levels in normal men.

The ability of single doses of a LHRH antagonist [Ac-delta 3Pro1, 4F-D-Phe2, D-Trp3,6]LHRH (4F-antagonist) to suppress serum gonadotropin and testosterone levels was studied in six normal men. The 4F-antagonist was given sc at four doses: 40, 80, 160, and 320 micrograms/kg body weight. Serum immunoreactive LH, FSH, and testosterone and bioactive LH were measured at intervals for the subsequent 18 h. Serum LH decreased rapidly by (mean +/- SE) 39.7 +/- 2.7%, 41.6 +/- 5.4%, 45.5 +/- 4.7%, and 45.3 +/- 5.4% after each of the four doses. The mean number of LH pulses and their amplitude decreased after each dose and remained suppressed for at least 6 h. After each of the four doses, mean serum FSH levels decreased by 20.0 +/- 4.1%, 33.8 +/- 6.8%, 25.8 +/- 3.6%, and 33.3 +/- 5.7%, and mean serum testosterone levels decreased by 47.7 +/- 7.3%, 55.6 +/- 10.5%, 58.2 +/- 10.8%, and 76.0 +/- 6.0%. Serum testosterone remained low for at least 18 h after the two higher doses. LH bioactivity and the ratio of bioactive LH to immunoreactive LH decreased in all subjects, especially after higher doses of the 4F-antagonist. No side effects or adverse reactions occurred after 4F-antagonist administration, and toxicology studies were negative. These results demonstrate that a single sc injection of this potent LHRH antagonist inhibits the pituitary-gonadal axis in normal men.

Diurnal variation in the response of plasma adrenocorticotropin and cortisol to intravenous ovine corticotropin-releasing hormone.

To determine whether the plasma immunoreactive ACTH (IR-ACTH) and IR-cortisol responses to ovine corticotropin-releasing hormone (oCRH) depend on the time of day, we administered 1 microgram/kg BW synthetic oCRH as an iv bolus dose to five normal men at their usual time of awakening between 0530-0740 h, at 1600 h, and at 2300 h. Mean basal plasma IR-ACTH and IR-cortisol levels were highest upon awakening, intermediate at 1600 h, and lowest at 2300 h, reflecting the diurnal rhythm of ACTH secretion. There was no significant difference in the plasma IR-ACTH response to oCRH at different times of the day. In contrast, the mean maximum plasma IR-cortisol increment and mean integrated response were 2- and 2.6-fold greater (P less than 0.05), respectively, at 2300 h than upon awakening. In another study, oCRH was given in the morning (0700-0900 h) to 22 normal men and in the late afternoon (1600-1800 h) to 24 normal men. Mean basal plasma IR-ACTH and IR-cortisol levels were significantly higher (P less than 0.001) in the morning [24 +/- 3 pg/ml (mean +/- SEM) and 10.6 +/- 0.8 micrograms/dl, respectively] than in the afternoon (13 +/- 2 pg/ml and 5.6 +/- 0.6 micrograms/dl, respectively). Mean peak plasma IR-ACTH was slightly greater in the morning (60 +/- 5.5 pg/ml) than in the afternoon (47 +/- 5.5 pg/ml), the mean maximum plasma IR-ACTH increments were the same (35 +/- 4 and 34 +/- 5 pg/ml, respectively), and the mean integrated IR-ACTH response was slightly less in the morning (2036 +/- 414 vs. 2365 +/- 358 pg . min/ml), but none of these differences was statistically significant. Mean peak plasma IR-cortisol concentrations in the morning and afternoon were similar (18.7 +/- 0.7 and 17.3 +/- 0.9 micrograms/dl, respectively), but the mean maximum plasma IR-cortisol increments (8.1 +/- 0.8 and 11.7 +/- 0.9 micrograms/dl, respectively; P less than 0.005), and the mean integrated IR-cortisol responses (588 +/- 115 and 976 +/- 95 micrograms . min/dl, respectively; P less than 0.01) were greater in the afternoon. There was an inverse correlation between basal plasma IR-cortisol concentration and the integrated IR-ACTH response (P less than 0.05), the maximum IR-cortisol increment (P less than 0.001), and the integrated IR-cortisol response (P less than 0.001).(ABSTRACT TRUNCATED AT 400 WORDS)

Effect of subcutaneous and intranasal administration of ovine corticotropin-releasing hormone in man: comparison with intravenous administration.

Long term use of ovine corticotropin-releasing hormone (oCRH) requires a convenient route of administration. The effects of 0.3, 3, and 30 micrograms/kg BW synthetic oCRH given as a sc injection and of 10 and 30 micrograms/kg given as an intranasal spray were studied in 10 normal men in the late afternoon. Basal plasma immunoreactive ACTH (IR-ACTH) and IR-cortisol levels were 14 +/- 1.9 pg/ml and 4.3 +/- 0.4 microgram/dl (mean +/- SEM). Peak IR-ACTH levels (mean +/- SEM) were 43 +/- 5.5, 53 +/- 8.1, and 64 +/- 8.9 pg/ml after the 0.3, 3, and 30 micrograms/kg doses of oCRH given sc, respectively, and 23 +/- 4.3 and 36 +/- 4.8 pg/ml after the 10 and 30 micrograms/kg doses of oCRH given intranasally, respectively. The lowest sc dose and both intranasal doses caused only single IR-ACTH peaks. After 3 and 30 micrograms/kg sc oCRH, IR-ACTH rose by 15 min, reached an initial peak at 45-60 min, fell rapidly until 90-120 min, and rose to a second peak at 3-5 h. This biphasic response is similar to that previously found after iv administration. IR-ACTH levels remained elevated for 4, 10, and at least 16 h after 0.3, 3, and 30 micrograms/kg sc oCRH, respectively, and for 1.5 and 3 h after 10 and 30 micrograms/kg intranasal oCRH respectively. The effect on IR-cortisol was similar, but more prolonged. Compared to the iv route, sc oCRH produced similar mean peak IR-ACTH and IR-cortisol levels and had a slightly longer duration of action. Intranasal oCRH was only about 1% as effective. Peak plasma IR-oCRH levels in 2 subjects receiving 3 micrograms/kg sc oCRH were 13 and 17 ng/ml at 90 min. These peaks were lower than those after iv administration of the same dose, but the levels remained elevated longer, probably accounting for the longer duration of action of sc oCRH. Peak plasma IR-oCRH levels in 4 subjects given 10 microgram/kg intranasal oCRH were only 64-122 pg/ml, presumably reflecting poor absorption through the nasal mucosa. These results demonstrate that sc injection of oCRH is at least as effective as the iv route with respect to plasma IR-ACTH and IR-cortisol responses. The convenience of this route of administration and the prolonged duration of action of oCRH suggest the feasibility of long term oCRH use.

Rapid sequential intravenous administration of four hypothalamic releasing hormones as a combined anterior pituitary function test in normal subjects.

Normal subjects were studied to test the feasibility of a combined anterior pituitary function test using iv administration of four hypothalamic releasing hormones: ovine corticotropin-releasing hormone, human GH-releasing hormone, GnRH, and TRH. Initially, nine normal men were studied with various combinations of these four hormones to exclude the possibility that they might inhibit or synergize with each other in releasing the individual anterior pituitary hormones. When given in combination, the releasing hormones were administered as sequential 20-sec iv infusions in the following order and doses: ovine corticotropin-releasing hormone, 1 microgram/kg; GnRH, 100 micrograms; human GH-releasing hormone, 1 microgram/kg; and TRH, 200 micrograms. Plasma or serum samples were assayed for ACTH, cortisol, GH, PRL, FSH, LH, and TSH at multiple times for 120 min after injection. Compared to individual administration, combined administration of these four hypothalamic releasing hormones caused no apparent inhibition or synergism with respect to the individual hormone responses of these normal subjects. Side-effects of the combined test were the same as those observed with individual hormone administration. No unusual or dangerous side-effects were observed. Having confirmed the efficacy of combined administration of the four releasing hormones, we administered the combination to five additional normal men and 12 normal women. Anterior pituitary hormone and cortisol responses were the same in men and women, except for a lower LH and a greater PRL response in women. There was a rapid increase in all hormones, with peak levels usually reached by 60 min. Adequate assessment of individual hormone responses can be achieved by assaying a basal and only 2 (or 3 in the case of ACTH and GH) postinfusion samples. A rapid, safe, and useful test of combined anterior pituitary function appears to be feasible using these four hypothalamic releasing hormones.

Clinical studies with synthetic ovine corticotropin-releasing factor.

Ovine corticotropin-releasing factor (oCRF) stimulates increased plasma immunoreactive adrenocorticotropin (IR-ACTH) and IR-cortisol at threshold, half-maximal, and maximal doses of 0.01-0.03, 0.3-1, and 3-10 micrograms/kg, respectively. Side effects occur with increasing frequency, severity, and duration at doses above 1 microgram/kg. oCRF has a prolonged duration of action, at least in part because of the long circulating half-life of intact oCRF in plasma. Increasing doses of oCRF given in late afternoon progressively diminish the next morning's circadian rise in plasma IR-ACTH in normal subjects, but not in Addisonian patients or subjects receiving metyrapone, indicating that prolonged oCRF-induced hypercortisolemia is the cause. Plasma IR-lipotropins and IR-beta-endorphin rise and fall concomitantly with IR-ACTH after oCRF injection. Arginine vasopressin increases the IR-ACTH response to oCRF fourfold when given simultaneously with oCRF. Cushing's disease patients respond variably, suggesting that oCRF may not be a very useful diagnostic agent in Cushing's syndrome. However, the combination of oCRF with growth hormone-releasing factor, gonadotropin-releasing hormone, and thyrotropin-releasing hormone appears to provide a rapid and useful test of combined anterior pituitary function.

Effect of synthetic ovine corticotropin-releasing factor: prolonged duration of action and biphasic response of plasma adrenocorticotropin and cortisol.

The duration of the response to synthetic ovine corticotropin-releasing factor (CRF) was studied in 13 healthy male volunteer subjects. Placebo or CRF (0.3, 3, or 30 micrograms/kg BW) was administered as an iv bolus or, in the case of the largest dose, a 30-sec infusion in single blind fashion in the late afternoon. Basal plasma immunoreactive ACTH (IR-ACTH) and IR-cortisol were 10.8 +/- 7.7 pg/ml and 5.0 +/- 1.8 micrograms/dl (mean +/- SD), respectively. IR-ACTH rose rapidly after CRF, reached an initial peak at 15 min, fell rapidly until 1.5 h after CRF, and then either fell more slowly (after the lowest dose) or rose to a second major peak at 2-3 h before falling back to baseline. After 0.3, 3, and 30 micrograms/kg CRF, IR-ACTH remained elevated for 4, 7, and 8 h, respectively. The effect on plasma IR-cortisol was similar, but more prolonged. The magnitude of both peaks of IR-ACTH, the duration of the response, and the area under the curve all appeared dose dependent. The same was true for IR-cortisol, except that the first peak height was similar after all three doses. The duration of CRF's action is probably due to its long circulating half-life. The biphasic response curve may reflect initial secretion of a readily releasable pool of ACTH, followed by later secretion of a second pool of newly synthesized and/or matured peptide. The next morning's normal circadian rise in both IR-ACTH and IR-cortisol was delayed and diminished after 3 micrograms/kg CRF; there was no increase in IR-ACTH after 30 micrograms/kg CRF, and the IR-cortisol level was diminished. Inhibition of the normal circadian rise may reflect inhibition of ACTH secretion by the sustained high plasma cortisol levels.

Effects of dietary lecithin on hormonal and neurobehavioral profiles in normal subjects.

Four normal subjects received lecithin supplements sufficient to elevate serum choline levels 3-fold. Despite persistent hypercholinemia over 48 hours of close observation, no increase was observed in serum ACTH, cortisol, and insulin concentrations, or in free urinary catecholamine excretion. Screening of a large group of other pituitary and gonadal hormones also failed to reveal any influence of lecithin supplements. EEG patterns and results of psychometric tests were also unaltered.

Effect of synthetic ovine corticotropin-releasing factor. Dose response of plasma adrenocorticotropin and cortisol.

Synthetic ovine corticotropin-releasing factor (CRF) was administered to normal male volunteer subjects as an intravenous bolus or 30-s infusion. Doses of CRF ranging from 0.001 to 30 micrograms/kg body wt were administered, and plasma immunoreactive (IR)-ACTH and IR-cortisol concentrations were measured. The threshold dose appeared to be 0.01-0.03 micrograms/kg, the half-maximal dose 0.3-1 micrograms/kg, and the maximally effective dose 3-10 micrograms/kg. Basal concentrations of IR-ACTH and IR-cortisol were 14 +/- 7.6 pg/ml (mean +/- SD) and 5.6 +/- 2.2 micrograms/dl, respectively. IR-ACTH rose as early as 2 min after CRF injection, reached peak levels in 10-15 min, and declined slowly thereafter. IR-cortisol rose at 10 min or later and reached peak levels in 30-60 min. At a dose of 30 micrograms/kg, neither IR-ACTH nor IR-cortisol fell from peak levels of 82 +/- 21 pg/ml (mean +/- SE) and 23 +/- 1.4 micrograms/dl, respectively, during the 2-h course of the experiment, indicating that CRF has a sustained effect on ACTH release and/or a prolonged circulating plasma half-life. There was little or no increase in the levels of other anterior pituitary hormones. At doses of 1 microgram/kg and higher, facial flushing, tachycardia, and, in some subjects, a 15-29-mmHg decline in systemic arterial blood pressure were observed, even though blood volume was replaced and the subjects remained supine. These data indicate that synthetic ovine CRF is a very potent and specific ACTH secretagogue in man. Administered with caution until its vasomotor effects are more fully defined, CRF promises to be a safe and very useful investigative, diagnostic, and, possibly, therapeutic agent in man.

Familial insensitivity of the pituitary and periphery to thyroid hormone: a case report in two generations and a review of the literature.

A clinically euthyroid 2-yr-old girl was found to have diffuse goiter that measured 3 X 5.5 cm with a prominent systolic bruit. Serum free T4 (3.4 ng/dl) and serum T3 (360 ng/dl) remained elevated for the next 10 months even though she remained clinically euthyroid. Elevation of serum free T4 (3.0 ng/dl) and serum T3 (265 ng/dl) was also present in the 24-yr-old nongoitrous mother who had symptoms and signs of hypothyroidism. Following intravenous injection of TRH, basal TSH levels of 2.7 and 2.8 microunits/ml increased to peak values of 17 and 21 microunits/ml at 30 min in the daughter and mother, respectively. Administration of exogenous T3 followed by sequential testing with boluses of TRH revealed retention of TSH responsiveness in both daughter and mother during pretreatment with dosage regimens of T3 below 125 micrograms daily. Maintenance of TSH responsiveness to TRH in the presence of elevated levels of serum free T4 and serum T3 indicates relative pituitary insensitivity to thyroid hormone which could be overridden by increasing the circulating levels of serum T3 three to fivefold over the already elevated basal levels. The absence of clinical signs of thyrotoxicosis indicates peripheral insensitivity to thyroid hormone with elevated circulating concentrations presumptively compensating for the defect. Resistance to thyroid hormone in two generations of the same family suggests genetic inheritance, and is concordant with four earlier reports of familial aggregation in this syndrome.