Hormone levels and tumour size response to quinagolide and cabergoline in patients with prolactin-secreting and clinically non-functioning pituitary adenomas: predictive value of pituitary scintigraphy with 123I-methoxybenzamide

BACKGROUND: Dopamine agonists are indicated as primary therapy for PRL-secreting pituitary adenomas, while controversial results have been reported in nonfunctioning adenomas (NFA). OBJECTIVE: To evaluate whether the in vivo visualization of dopamine D2 receptor expression detected by pituitary scintigraphy using 123I-methoxybenzamide (123I-IBZM) was correlated with the response to chronic treatment with quinagolide or cabergoline. PATIENTS: 10 patients affected with NFA (5 men and 5 women, age ranging between 25 and 50 years), and 10 with PRL-secreting naive macroadenomas (3 men and 7 women, age ranging between 22 and 59 years), serving as control. STUDY DESIGN: All patients underwent an acute test with quinagolide: at 3-day intervals and in random order all patients received the drug (0.075 mg at 0800 h), or placebo. Blood samples were taken 15 and 5 minutes before and every 30 minutes for 6 h after drug or placebo administration. The test was considered positive when PRL and/or alpha-subunit levels decreased >/=50% as compared to baseline levels. After 6 months of treatment, 10 patients were randomised to continue the treatment with quinagolide and the remaining 10 received cabergoline for the remaining 6 months. The doses of quinagolide and cabergoline ranged from 0.075 to 0.6 mg/day and from 0.5 to 3 mg/week, respectively. At study entry, a magnetic resonance imaging (MR) study of the pituitary region and 123I-IBZM pituitary scintigraphy were performed. MR was repeated after 12 months of treatment to evaluate tumour shrinkage: reduction of tumour volume = 80% in prolactinomas and = 50% in NFA was considered significant. Basal PRL levels were 9495.0 +/- 1131.6 mU/l in prolactinomas and 602.4 +/- 50.5 mU/l in NFA. RESULTS: The scintigraphy was negative in 6 out of 10 patients with NFA. Moderate uptake was observed in 3 patients with prolactinoma and 2 patients with NFA whereas intense uptake was observed in the remaining 7 patients with prolactinoma and 2 patients with NFA. Among the 8 patients with NFA and high circulating alpha-subunit levels, the acute test was negative in 5 while it was positive in the remaining 3 patients. The acute test was positive in all 10 patients with prolactinoma. After 12 months of treatment with quinagolide and cabergoline, circulating PRL levels were decreased in all 10 patients with prolactinoma (571.8 +/- 255.9 mU/l), being normalized in 7 patients. Suppression of PRL levels was found in all 10 patients with NFA (89.5 +/- 2.3 mU/l). A significant reduction of alpha-subunit levels was obtained in 9 out of 10 patients with NFA: in 4 out of 8 patients alpha-subunit levels were normalized. Significant adenoma shrinkage was recorded in 4 patients with prolactinoma among the 7 with intense pituitary uptake of 123I-IBZM. Significant adenoma shrinkage was recorded only in the 2 out of 10 patients with NFA with intense pituitary uptake of 123I-IBZM. A significant positive correlation was found between the degree of uptake (considered as score) and the response to quinagolide or cabergoline treatment (considered as percent hormone suppression) either in patients affected with PRL-secreting adenoma (r = 0.856, P < 0.005) or in those affected with NFA (r = 0.787, P < 0.05). CONCLUSIONS: An intense 123I-IBZM uptake in patients with non-functioning adenomas was predictive of a good response to a chronic treatment with quinagolide and cabergoline. This result suggests that a pituitary 123I-IBZM scintigraphy could be considered in selected patients with non-functioning adenomas before starting medical treatment with dopamine agonists.     

The luteinizing hormone-releasing hormone (LHRH) agonist [D-Trp6-Pro9-NEt]LHRH increased rather than lowered LH and alpha-subunit levels in a patient with an LH-secreting pituitary tumor

Episodic secretion of LH, and the responses of serum LH, alpha-subunit, and testosterone concentrations to the acute administration of LHRH and the chronic administration of the LHRH agonist analog [D-Trp6-Pro9-NEt]LHRH (D-Trp6-Pro9) were evaluated in a 33-yr-old man previously reported to have an LH-secreting pituitary tumor unaccompanied by FSH hypersecretion. Basal serum LH and alpha-subunit concentrations were elevated [57 +/- 0.7 (SEM) mIU/ml (range, 45-71) and 26 ng/ml, respectively]. Frequent sampling revealed six LH secretory spikes over a 24-h period with increments above basal levels varying from 23-40% and interspike intervals ranging from 1.5-5 h. The concentrations of LH or alpha-subunit after iv administration of 150 micrograms LHRH did not increase above these intrinsic LH secretory increments (delta LH: 23%; delta alpha-subunit: 21%). The low basal serum FSH concentrations (3.5 mIU/ml) and elevated basal serum testosterone levels (1480 ng/dl) were unchanged after LHRH. Administration of clomiphene citrate produced no increase in serum LH, FSH, or testosterone concentrations. An attempt was made to decrease LH secretion in this patient using D-Trp6-Pro9. Administration of 200 micrograms daily sc of this LHRH analog for 21 days was associated with increases in serum LH and alpha-subunit concentrations. Mean serum LH and alpha-subunit levels for the 21 days of analog administration were 110 +/- 5.4 (SEM) mIU/ml (range, 70-170) and 64 +/- 3 (SEM) ng/ml (range, 32-84), respectively. During the 9-day period after discontinuance of the LHRH analog, levels of both serum LH and alpha-subunit declined precipitously and mean serum LH and alpha-subunit levels were 58 +/- 7 (SEM) mIU/ml (range, 18-90) and 22 +/- 3 (SEM) ng/ml (range, 12-44), respectively. We conclude that this patient's pituitary tumor has diminished responsiveness to acute LHRH administration and that the effect of chronic D-Trp6-Pro9 is stimulatory rather than inhibitory, as occurs after chronic administration of this analog to normal subjects. The blunted responsiveness to LHRH administration and the lack of response to clomiphene citrate suggest tumor autonomy. The presence of modest paradoxical responsiveness of serum LH and alpha-subunit concentrations during the course of daily D-Trp6-Pro9 administration suggests that central regulatory mechanisms, if present, are abnormal.     

Long-term treatment with the dopamine agonist CV 205–502 of patients with a clinically non-functioning, gonadotroph, or α-subunit secreting pituitary adenoma

OBJECTIVE: We aimed to assess the effects of prolonged treatment with the dopamine agonist CV 205-502 on tumour volume, visual field defects, and serum gonadotrophin and alpha-subunit concentrations in patients with gonadotroph, alpha-subunit secreting, or clinically non-functioning pituitary adenomas. DESIGN: The patients were treated with CV 205-502 in a final daily dose of 300 micrograms for at least 1 year. The patients were seen at 2 or 3-week intervals during the first 3 months of treatment, and thereafter every 1 or 2 months. Computerized tomography and Goldmann perimetry were performed before treatment and during follow-up. Blood samples were drawn before treatment and at each out-patient visit. PATIENTS: One patient with gonadotroph, two with alpha-subunit secreting, and two with clinically non-functioning pituitary adenomas were studied. RESULTS: Computerized tomography showed tumour shrinkage in one patient. In two other patients an improvement of visual field defects was observed. In four patients, a significant decrease in serum FSH and/or alpha-subunit concentrations occurred within the first 3 months of treatment. In the remaining patient, a significant decrease of serum FSH and alpha-subunit concentrations was found after more than 3 months of treatment. CONCLUSIONS: In patients with clinically non-functioning, gonadotroph, or alpha-subunit secreting pituitary tumours, long-term treatment with the dopamine agonist CV 205-502 decreases serum FSH and/or alpha-subunit concentrations. This decreased secretory activity from the pituitary tumour may be accompanied by an improvement of visual field defects, or tumour shrinkage on computerized tomography. Therefore, treatment with CV 205-502 may be useful in patients with clinically non-functioning, gonadotroph, or alpha-subunit secreting pituitary tumours, who cannot be operated upon.     

Combined βFSH and βLH response to TRH in patients with clinically non-functioning pituitary adenomas

OBJECTIVE‘Paradoxical’ responses of LH, FSH, α-subunits and βLH to TRH have previously been reported in individuals with clinically non-functioning pituitary tumours (NFT). The present study was designed to assess the in vivoin vitro responses of βFSH to TRH in NFT. We further examined the possibility that a TRH challenge with combined measurement of βFSH and βLH will identify a common anomalous secretory pattern in patients with NFT. DESIGN, PATIENTS AND MEASUREMENTSForty patients with NFT underwent a standard TRH test (400 μg intravenously). Blood samples for the determination of βFSH, βLH, FSH and LH were collected prior to TRH as well as 15, 30, 45, 60 and 90 minutes following injection. Additionally, cultured adenomatous cells from eight of these patients were exposed to TRH in the absence and presence of octreotide and gonadotropin subunits were determined. RESULTSTRH elicited a marked rise in circulating βFSH in 29 of 40 individuals and in βLH in 28 of 36 patients with NFT. In a subgroup of eight individuals whose tumours were harvested during surgery and cultured for 7–21 days, TRH increased βFSH or βLH and α-subunit release in cultured adenomatous cells in all cases, including tumours from subjects not responding to TRH in vivo. In this subgroup of patients octreotide inhibited basal βFSH secretion but not basal βLH secretion both in vivo and in primary cultures of NFT cells. Both the in vivoin vitroβFSH, βLH and α-subunit responses to TRH were entirely inhibited by octreotide. In all, 38 of the 40 subjects could be identified by either elevated basal βFSH or βLH levels and/or an abnormal rise in either βFSH or βLH in response to TRH. CONCLUSIONThe measurement of basal and TRH-stimulated β-FSH and β-LH levels identifies an abnormal hormonal secretory pattern in the vast majority (>90%) of patients with clinically nonfunctioning pituitary tumours.     

Increased luteinizing hormone sensitivity to dopaminergic inhibition in Graves' disease

The effect of dopamine infusion (4 micrograms X kg-1 X min-1 from 9.00 to 13.00 h) on serum LH and FSH concentrations were studied in 15 patients (10 women, 5 men) with diffuse toxic goitre, and 10 healthy subjects (6 women, 4 men). Basal serum LH (17.0 +/- 0.8 IU/l) and oestradiol (women: 3.74 +/- 1.84; men: 3.05 +/- 0.77 pmol/l) were elevated in patients, whereas serum FSH and PRI were normal. Dopamine infusion did not modify serum FSH levels, but significantly depressed LH concentration in both hyperthyroid and healthy subjects. The LH decrement was more pronounced (P less than 0.01) in patients with Graves' disease (8.4 +/- 1.4 IU/l) as compared with controls (2.3 +/- 0.9 IU/l). There was a positive correlation between the maximum net decrease and the basal LH concentration (r = 0.95). The per cent decrease of LH levels in the hyperthyroid patients (54 +/- 4) was higher (P less than 0.001) than that in the controls. The finding of enhanced sensitivity to dopamine inhibition in thyrotoxic patients suggests that their inappropriately elevated serum LH levels may result in part from a reduced dopaminergic inhibition of LH secretion.     

PLASMA INHIBIN LEVELS IN MEN WITH CHEMOTHERAPY-INDUCED SEVERE DAMAGE TO THE SEMINIFEROUS EPITHELIUM

Immunoreactive plasma inhibin levels and free testosterone index (FTI) were estimated in 17 patients who had previously received combination chemotherapy for Hodgkin's disease and in 16 age-matched controls. In the same patients we had previously found significantly raised FSH and LH levels in the presence of normal basal and HCG-stimulated total testosterone levels. Mean plasma inhibin levels were not different between the patients (601 +/- 321 U/l) and controls (530 +/- 174 U/l) nor were FTI values (81.5 +/- 35 vs 91 +/- 47 respectively). There was a positive correlation (r = 0.53, P less than 0.05) between FSH and inhibin levels and a negative correlation between FSH and FTI (r = -0.51, P less than 0.05) in the patients but not in the controls. No such correlations with inhibin or FTI existed for LH but there was a positive correlation between LH and FSH levels in the patients. In four patients inhibin levels were pathologically raised and in this group mean FSH values (21.7 +/- 4.7 IU/l) were higher (P less than 0.001) and mean FTI (59.1 +/- 22.6) lower (P less than 0.001) than respective values (13.6 +/- 5.3 IU/l and 88.4 +/- 35) for the remainder of the patients. These data are not compatible with the hypothesis that inhibin is the major negative feedback signal for the control of FSH secretion.     

QUANTITATIVE AND QUALITATIVE CHANGES IN LH SECRETION FOLLOWING PULSATILE GnRH THERAPY IN A MAN WITH IDIOPATHIC HYPOGONADOTROPHIC HYPOGONADISM

The pattern of bioactive and immunoreactive LH secretion before and during pulsatile GnRH therapy (18 micrograms/90 min) in a hypogonadotrophic hypogonadal male has been studied. Before treatment the patient was azoospermic and had low testosterone (1.2 nmol/l) with low and apulsatile immunoreactive LH (1.9 +/- 0.2 IU/l) and FSH (1.4 +/- 1.9 IU/l) levels. There was no detectable LH bioactivity. During the first 24 h of GnRH therapy there was a small increase in immunoreactive (5.4 +/- 0.8 IU/l) and bioactive (6.7 +/- 1.3 IU/l) LH, with an irregular pattern and little effect on testosterone production (2.2 nmol/l). Within 1 week of treatment both bioactive (30.5 +/- 6.8 IU/l) and immunoreactive (13.6 +/- 1.5 IU/l) LH levels were above the normal range and the pattern of secretion was pulsatile. The bioactive to immunoreactive (B:I) LH ratios within the pulses (2.6 +/- 0.3) were higher (P less than 0.01) than between pulses (1.97 +/- 0.1) and the testosterone concentration (17.8 +/- 2.1 nmol/l) was now normal. At one month LH secretion was similar and testosterone pulses of high amplitude were evident corresponding to high-amplitude bioactive LH pulses. By 3 months mature spermatozoa (1.3 x 10(6)/ml) were seen in the patient's semen. The pattern of LH secretion was pulsatile but the levels of bioactive (13.1 +/- 3.6 IU/l) and immunoreactive (9.5 +/- 1.3 IU/l) LH decreased towards the normal range reflecting maturation of the testicular feedback control at the pituitary level. This effect was more pronounced on bioactive rather than immunoreactive LH secretion (57% vs 32% relative decrease). At 6 months LH levels were similar and the sperm count was normal (34 x 10(6)/ml).     

Glycoprotein hormone alpha-subunit response to growth hormone (GH)-releasing hormone in patients with active acromegaly. Evidence for alpha-subunit and GH coexistence in the same tumoral cell

Basal serum concentrations of glycoprotein hormone alpha-subunit and its response to GH-releasing hormone (GHRH) were studied in 22 acromegalic patients and in normal subjects. Four out of 22 patients had a basal alpha-subunit concentration (1.2-3.5 ng/ml) clearly above the upper limit of the normal range. GHRH injection (1 microgram/kg body weight, bolus dose iv) produced a clear alpha-subunit response [mean % increase: 120 +/- 37 (SD)] in the 4 patients with elevated basal alpha-subunit levels. No increase in serum glycoprotein hormones (TSH, LH, and FSH) occurred. Selective adenomectomy in 2 patients resulted in normalization of both serum GH and alpha-subunit levels, as well as disappearance of the abnormal alpha-subunit response to GHRH. In in vitro studies, only these 2 adenomas secreted alpha-subunit in large amounts (534 and 388 ng/mg protein . 30 min) and was it further stimulated by GHRH (% increase: 83 and 126). Morphological studies done with protein A-gold particle immunotechnique demonstrated that in these adenomas the great majority of the cells contained secretory granules positive for both GH and alpha-subunit. We conclude that: 1) alpha-subunit hypersecretion is present in some acromegalic patients (about 20%), 2) GHRH stimulates alpha-subunit release both in vivo and in vitro only in patients with elevated basal alpha-subunit levels, and 3) in these patients alpha-subunit derives from a common adenomatous cell secreting both alpha-subunit and GH molecules.     

Abnormal response of luteinizing hormone beta subunit to thyrotrophin-releasing hormone in patients with non-functioning pituitary adenoma

OBJECTIVE it has been suggested that the response of free β-subunit of LH (LHβ) to TRH Is the most useful in-vivo marker of gonadotroph adenomas in patients with non-functioning pituitary adenomas (NFPA). The aim of the present study was to investigate LHβ secretion in patients with NFPA in whom other markers of gonadotroph adenomas, such as supranormal basal concentrations or responses of intact gonadotrophins to TRH, were absent. DESIGN AND PATIENTS Serum basal levels Of LHβ, LH and FSH were evaluated in 80 patients with NFPA showing normal levels of intact gonadotrophin, 20 with PRL-secreting adenomas, 25 with OH-secreting adenomas and 58 healthy subjects. Moreover, LHβ, LH, FSH and alpha-subunit (α-SU) were evaluated in 27 patients with NFPA In whom intact gonadotrophin responses to TRH were absent, 8 with PRL-oma, 7 with GH-oma and 17 healthy subjects before and 20,30 and 60 minutes after the intravenous administration of either 200 μg TRH or placebo. A response was considered present when serum LHβ increased by at least 50% above basal levels. MEASUREMENTS LHβ was evaluated using a new assay based on the sequestration of the combined and free α-SU by an anti α-SU blotinylated monoclonal antibody (MAb) and the subsequent measurement of the LHβ by an IFMA method employing two MAbs directed towards two different epitopes on LHβ. intact LH and FSH were assayed with an IFMA method and α-SU with an IRMA method. RESULTS in basal conditions, no significant difference in the mean values of LHβ was observed among patients with different types of tumour and normal controls. In 9 of 27 (33%) patients with NFPA, TRH caused an abnormal elevation of serum LHβ (net increase 410 ± 403%, range 71-1300) which was completely dissociated from changes in intact gonadotrophins. Of the 5 patients who had a TRH test repeated after transsphenoidal surgery, abnormal LHβ responses disappeared in 2 and were maintained in 3. Disappearance of LHβ response occurred only in patients in whom improvement of visual field and radiological imaging after adenomectomy was observed. in contrast, in ail patients with pituitary tumours other than NFPA and healthy subjects a response to TRH was absent (net increase ranging from 0 to 23%). immunofluorescence, performed on 14 NFPA removed from patients either responsive or unresponsive to TRH, showed a variable proportion of cells positive for LHβ, without a significant difference between the two groups. CONCLUSIONS These results indicate that measurement of basal LHβ is of poor value in the diagnosis of non-functioning pituitary adenomas and the identification of gonadotroph adenomas among non-functioning pituitary adenomas. Conversely, an abnormal response of free LHβ to TRH occurs in about a third of patients with low/normal basal gonadotrophins unresponsive to TRH stimulation.     

Recovery of growth hormone secretion following cabergoline treatment of macroprolactinomas

OBJECTIVE: Cabergoline therapy normalizes prolactin levels and reduces the size of macroprolactinomas. However there are no data indicating whether cabergoline can normalize growth hormone secretion in patients who were growth hormone deficient at the time of diagnosis of a macroprolactinoma. SUBJECTS AND METHODS: We studied nine patients with biochemical and radiological evidence of a macroprolactinoma who were also growth hormone deficient (peak growth hormone response to insulin-induced hypoglycaemia < 10 mU/l). Patients were assessed before and after cabergoline therapy to assess their growth hormone secretory status, IGF-I levels, cortisol response and change in tumour size. RESULTS: Treatment with cabergoline was associated with a significant reduction in prolactin concentration (74341 +/- 31939 mU/l vs. 265.9 +/- 86.3, P = 0.009). The mean change in peak growth hormone response to insulin-induced hypoglycaemia was significantly greater following cabergoline therapy compared with pretreatment levels (33.5 +/- 11.8 mU/l vs. 4. 34 +/- 1.21 mU/l, P = 0.022). However IGF-I levels were not different after treatment when compared with baseline although a nonsignificant trend towards improvement was noted (24.2 +/- 3.97 nmol/l vs. 18.4 +/- 4.94 nmol/l, P = 0.058). The mean peak cortisol concentration was 407.7 +/- 64.1 nmol/l before treatment with a nonsignificant rise to 477.4 +/- 84.8 nmol/l, P = 0.813 after treatment. These changes were associated with a significant reduction in mean maximal tumour diameter (21.2 +/- 2.9 mm vs. 29.1 +/- 2.8 mm, P = 0.009). There was no significant difference in either prolactin concentration or tumour size pre- or post-treatment between those who recovered growth hormone secretion and those that did not. Six of the nine (67%) patients recovered a normal growth hormone response (> 10 mU/l) after cabergoline therapy. Those that remained growth hormone deficient after treatment were all panhypopituitary at baseline while those that recovered showed only partial anterior hypopituitarism. CONCLUSION: These data indicate that growth hormone secretion may recover following successful reduction of prolactin levels after cabergoline therapy for a mean of 22 months (range 6-28 months) in most but not all subjects with a macroprolactinoma. It is therefore advisable that individuals with a macroprolactinoma in whom growth hormone replacement therapy is being considered undergo repeat assessment of growth hormone secretion following medical treatment.     

Gonadotropic insufficiency in men with disorders of spermatogenesis

The results of the investigation of 111 male patients with azoospermia, oligozoospermia and asthenoteratozoospermia revealed gonadotropic insufficiency in 28 (25.2%). The mean level of LH in the peripheral blood of the patients (4.36 +/- 0.70 IU/l) did not differ significantly from the indices in the control group (5.71 +/- 0.64 IU/l). The blood FSH level (0.86 +/- 0.13 IU/l) was significantly lower than the control one (4.48 +/- 0.44 IU/l), p less than 0.001. The level of testosterone in 14 patients was within normal. The clinical signs of hypogonadism were slightly expressed, gynecomastia and anosmia were absent. In 6 of 11 patients the response of FSH to LH-RH i. v. injection was either absent or sharply decreased. The LH response was absent in 2 patients. A conclusion has been made that disorder of spermatogenesis can be the only noticeable manifestation of isolated insufficiency of FSH secretion by the pituitary gland.     

Naloxone administration does not affect gonadotropin secretion in patients with Klinefelter's syndrome

Plasma LH and FSH were measured every 20 min in a group of patients with Klinefelter's syndrome before and after placebo or naloxone administration (8 mg iv as a bolus followed by an infusion of 4 mg/h for 4 h) both in baseline conditions (N = 6) and during treatment with testosterone enanthate (200 mg im every two weeks; N = 4). The mean LH areas measured during saline infusion in baseline conditions (7888 +/- 758 IU/l per min mean +/- SEM) and during testosterone treatment (5042 +/- 2039 IU/l per min) were not significantly different from those measured during naloxone infusion (baseline 8317 +/- 818 IU/l per min; during testosterone treatment 5395 +/- 2007 IU/l per min). Similar results were obtained for FSH. These data suggest that in patients with Klinefelter's syndrome, the opioidergic inhibition of gonadotropin release is lacking and is not restored by testosterone replacement therapy.     

Reduction of gonadotropin-releasing hormone pulse frequency is associated with subsequent selective follicle-stimulating hormone secretion in women with polycystic ovarian disease

Polycystic ovarian disease (PCO) is characterized by hyperandrogenism, ovulatory dysfunction, and altered gonadotropin secretion. Mean plasma FSH concentrations are low, while LH is elevated in a majority of patients. LH pulsatile secretion has been shown to occur at rapid follicular phase frequencies (approximately one pulse per h) in PCO, suggesting persistent rapid frequency GnRH secretion in this disorder. Anovulatory women with PCO were given estradiol (E2; Estraderm skin patches) and progesterone (P; vaginal suppositories) to produce midluteal concentrations for 21 days. The aim was to determine if E2 and P would slow LH (GnRH) pulse frequency and if this would result in augmented FSH secretion and follicular development after withdrawal of E2 and P. Plasma LH was measured every 10 min for 8 h before, during (days 10 and 20), and 7 days after withdrawal of E2 and P (day 28). On each of these study days FSH was measured hourly, and E2 and P were measured every 2 h. After sampling, GnRH (25 and 250 ng/kg, iv) was given to assess pituitary responsiveness. Follicular development was monitored by vaginal ultrasound through day 34 of the study. Basal LH frequency was 8.5 +/- 0.5 pulses/8 h (mean +/- SEM). During E2 and P, LH pulse frequency fell to 3.3 +/- 1.0 (10 days) and 2.3 +/- 0.8 (20 days), 39% and 27% of the basal value, respectively, and subsequently increased to 5.6 +/- 0.7 (66% of basal) 7 days after withdrawal of E2 and P. LH pulse amplitude (basal, 7.2 +/- 1.5 IU/L) was not reduced until day 20, but remained suppressed (3.9 +/- 1.1 IU/L) on day 28. As a result, mean LH (basal, 21.0 +/- 3.5 IU/L) fell progressively during E2 and P, to 3.8 +/- 1.2 IU/L on day 20, and remained low (39% of basal) 7 days after steroid withdrawal. Mean plasma FSH (basal, 7.1 +/- 0.9 IU/L) also fell during steroid administration, but in contrast to LH, had risen to 93% of the basal value by 7 days after E2 and P. LH release in response to exogenous GnRH revealed marked initial responses which did not decrease until day 20, but remained suppressed (8% of basal) after withdrawal of E2 and P. FSH responses were also suppressed on day 20, but had increased to 75% of the basal value by day 28. Initiation of follicular development occurred in all patients, and the lead follicle measured 12.3 +/- 0.8 mm 13 days post-E2 and P. Ovulation occurred in one patient.(ABSTRACT TRUNCATED AT 400 WORDS)     

Administration of low dose pulsatile gonadotropin-releasing hormone (GnRH) to GnRH-deficient men regulates free alpha-subunit secretion

Although pharmacological doses of GnRH and TRH stimulate free alpha-subunit (alpha-subunit) secretion from the pituitary, little is known about the pattern and control of alpha-subunit release under physiological circumstances. Euthyroid men with idiopathic hypogonadotropic hypogonadism, a condition of deficient GnRH release, provide a unique opportunity to study alpha-subunit secretion before and during administration of a physiological regimen of GnRH administration. Before GnRH therapy, six euthyroid IHH men with normal endogenous TSH secretion had circulating alpha-subunit levels close to or below assay detection limits, with a mean level less than 0.5 ng/ml. During 12-42 weeks of physiological GnRH replacement, serum alpha-subunit concentrations rose to a mean value of 2.07 +/- 0.3 (+/- SEM) ng/ml (P less than 0.01). After GnRH administration, alpha-subunit was released in a pulsatile pattern following each dose of GnRH and mirrored the secretory pattern of LH. Increases in serum alpha-subunit concentrations during GnRH administration were closely correlated with increases in LH (r = 0.91; P less than 0.01), but not FSH (r = 0.24; P = NS), levels. In addition, a situation in which LH secretion was clearly predominant and FSH levels were barely detectable was created by increasing the frequency of GnRH administration to every 30 min. In this circumstance, free alpha-subunit concentrations increased in conjunction with LH levels in the face of decreased FSH levels. We conclude that replacement of GnRH regulates both the level and pattern of alpha-subunit secretion in GnRH-deficient men, and that there is tight correlation of alpha-subunit with LH, but not with FSH, secretion.     

Influence of sodium valproate on late follicular phase pulsatile LH secretion in normal women

OBJECTIVE: The present study was designed to further assess the mechanism of action of GnRH and GnRH analogues. DESIGN AND PATIENTS: Both the Nal-Glu GnRH antagonist and the D-Trp6 GnRH agonist were administered sequentially to nine normal, post-menopausal women. MEASUREMENTS: A baseline study of pulsatile LH, FSH and free alpha-subunit secretion was performed, with sampling every 10 min for 8 h, and then repeated 8 h after a single subcutaneous injection of Nal-Glu GnRH antagonist (5 mg). Sampling was repeated 21 days after the intramuscular injection of a depot preparation of D-Trp6 GnRH (3.75 mg) in the same women. RESULTS: The baseline sampling period showed synchronous pulses of LH and free alpha-subunit. The antagonist Nal-Glu decreased plasma LH (71%) and free alpha-subunit (43%). However, with the single dose of 5 mg, pulsatile LH and free alpha-subunit release were not completely suppressed and remained temporally correlated. The GnRH agonist had a potent inhibitory action on plasma immunoreactive LH (IRMA) (93%). In contrast, it increased the mean plasma levels of free alpha-subunit from 1.66 +/- 0.01 to 5.06 +/- 0.02 micrograms/l (205%). The pulsatile secretory patterns of both LH and free alpha-subunit were abolished by the agonist. Immunoreactive FSH levels were decreased by the antagonist (24%) and suppressed by the agonist (93%). CONCLUSIONS: The pulsatile study confirms the different mechanism of action of GnRH analogues. Following antagonist administration, low amplitude free alpha-subunit pulses persist and are synchronous with residual LH pulses. In contrast, LH and free alpha-subunit are not maintained under agonist treatment. These data provide evidence for the differential regulation of LH and free alpha-subunit by GnRH.     

Stimulation of ovarian follicular maturation with pure follicle-stimulating hormone in women with gonadotropin deficiency

According to the 2-cell theory, ovarian steroidogenesis requires the coordinate action of both FSH and LH. To evaluate the relative importance of these hormones in follicular maturation, a randomized cross-over study was performed in 10 women with complete gonadotropin deficiency (absence of pulsatile LH secretion and no LH response to LHRH). Five women were treated with highly purified FSH (LH bioactivity, 0.09%) and 3 months later with human menopausal gonadotropin (hMG; LH bioactivity, 65%), each given for 10 days at a daily dose of 225 IU FSH, im. The sequence was reversed in the other 5 women. hCG (5000 IU) was administered im 24 h after the last injection of FSH or hMG. Plasma estradiol (E2), estrone (E1), androstenedione (A), testosterone, LH, and FSH concentrations and urinary LH and FSH were measured daily by RIA. Ultrasonography was performed during each treatment and 2 days after each hCG injection. After FSH treatment, mean plasma and urinary FSH levels increased, mean plasma LH did not change, and urinary LH increased slightly but not significantly from 91 +/- 32 (SE) to 164 +/- 55 mIU/24 h (10(-3) IU/24 h). After hMG treatment, mean plasma and urinary LH and FSH levels increased accordingly. The mean basal plasma E2 [11 +/- 1 pg/mL (40 +/- 4 pmol/L)] and E1 [14 +/- 4 pg/mL (52 +/- 15 pmol/L)] levels increased after FSH treatment to 207 +/- 69 pg/mL (760 +/- 253 pmol/L) and 82 +/- 21 pg/mL (303 +/- 78 pmol/L), respectively (P less than 0.01), but plasma A did not change. In response to hMG, the mean plasma E2, E1, A, and testosterone levels increased more than during FSH treatment. Ultrasonography revealed multiple preovulatory follicles (greater than or equal to 16 mm) in 2 women after hMG and 1 woman after FSH treatment; therefore, hCG was not administered. In 3 women given FSH, hCG did not induce ovulation. hCG induced ovulation in 8 women given hMG and in 6 women given FSH, based on ultrasonography and plasma progesterone levels. Thus, in the presence of profound gonadotropin deficiency pharmacological doses of FSH, with minute LH contamination, are capable of stimulating ovarian follicular maturation, underlining the key role of FSH in folliculogenesis.     

DISCORDANT SERUM α-SUBUNIT AND FSH CONCENTRATIONS IN A WOMAN WITH A PITUITARY TUMOUR

We have studied a women who presented at the age of 51 with a large FSH and alpha-subunit producing pituitary adenoma. Following insertion of ventriculo-peritoneal shunts and external pituitary irradiation there was no change in the elevated serum concentrations of FSH, and alpha-subunit over a four year period although she developed both ACTH and TSH deficiency. Various drugs, however, did alter the FSH and alpha-subunit concentrations and these changes suggest possible mechanisms controlling FSH secretion. Ethinyloestradiol 0.03 mg daily for three weeks suppressed serum FSH to 77% of the basal level (240 +/- 35 i.u./l to 184 +/- 20 i.u./l) but alpha-subunit rose to 130% of basal level (281 +/- 50 ng/ml to 366 +/- 40 ng/ml). On ethinyloestradiol 0.1 mg daily, FSH suppressed to 17% of basal (40 +/- 11 i.u./l) with no change in alpha-subunit concentration, while on 0.2 mg daily suppression of FSH was similar but alpha-subunit fell to 59% of basal (190 +/- 28 ng/ml). Dexamethasone, 3 mg daily for one week reduced FSH to 53% of the initial concentration and alpha-subunit to 74% while bromocriptine 7.5 mg daily for three months, reduced FSH to 39% and alpha-subunit to 66% of basal. Neither thyroxine, 0.2 mg daily for four weeks, nor an LHRH analogue, (Buserelin, Hoechst) 200 micrograms, three times daily for three months elicited any effect. Chromatography on Sephadex G100 showed that serum FSH and alpha-subunit both had Kav values somewhat lower than those of their standard counterparts (FSH, 0.20 vs 0.25; alpha-subunit 0.35 vs 0.45).(ABSTRACT TRUNCATED AT 250 WORDS)     

Circadian, ultradian, and episodic gonadotropin and prolactin secretion in human pseudocyesis

Six women with pseudocyesis were studied by 15-min blood sampling for 12 to 24 h to determine their gonadotropin and PRL secretory profiles aiming to clarify the endocrine alterations in this form of hypothalamic amenorrhea. Clinical and biochemical evidence of hyperandrogenism was found in 4 patients. Persistent hyperprolactinemia was present only in one patient. Significant circadian and ultradian periodicities were identified by time series analysis in the 12-24 h profiles of FSH, LH and PRL secretion. Pulse analysis by the Van Cauter (UL-TRA.JN) method revealed a 24-h mean LH interpulse interval of 91 +/- 21 min with a mean LH amplitude of 5.4 +/- 0.8 IU/l. There was a significantly lower pulse frequency at night than during the daytime. The mean 24-h PRL interpulse interval and pulse amplitude were 134 +/- 22 min and 9.2 +/- 1.8 IU/l, respectively. Both FSH and LH mean levels were higher during the daytime than at night, while the reverse was true for PRL values. Decreased LH pulse frequency and amplitude emerged as the most distinctive findings. Antecedent hypothalamic-pituitary aberrations due to other endocrinopathies and the timing of the hormonal assessment (e.g. recovery phase) may explain, at least in part, the reported heterogeneity of neuroendocrinologic findings in pseudocyesis.     

Follicle stimulating hormone-secreting pituitary adenoma: inappropriate secretion and effect of pulsatile luteinizing hormone releasing hormone analogue (buserelin) administration.

A patient with an FSH secreting pituitary adenoma is reported. Elevated FSH and serum free alpha-subunit (SU) with low levels of LH and testosterone (T) were found. Immunostaining showed the presence of alpha-SU, FSH-beta and LH-beta subunits. LHRH analogue (buserelin) was administered in a pulsatile manner, by portable computerized infusion pump sc for ten days. During the first 24 h of treatment FSH, LH (p less than 0.001) and T (p less than 0.01) rose significantly. Ten days later, the expected desensitization phenomenon did not occur, but further increases of T (8.4 +/- 2.6, mean +/- SD, vs 17.4 +/- 4.1 nmol/l, p less than 0.001) and FSH (58.9 +/- 9.6 vs 70.7 +/- 3.8 mlU/ml, p less than 0.001) were registered. LH decreased (12.5 +/- 2.4 vs 7.1 +/- 0.6 mlU/ml, p less than 0.001) at day 10, but remained higher than basal level (5.0 +/- 0.6, p less than 0.001). Free alpha-SU also rose (2.8 +/- 0.4 vs 4.4 +/- 1.7 mlU/ml, p less than 0.001) after ten days of treatment. The chronic stimulatory effect of analogue on LH with a lack of desensitization suggests tumorous secretion despite a partially preserved negative feedback of testosterone. Low basal LH levels, in some patients with FSH secreting tumors may not be due to tumor mass effect, but rather may be the consequence of altered LH production and/or secretion by the tumor. Although buserelin may not have a therapeutic effect, it is of use in differential diagnosis of hypergonadotropinemia.     

Ovarian hyperstimulation without elevated serum estradiol associated with pure follicle-stimulating hormone-secreting pituitary adenoma

We report a unique case of a 28-yr-old woman with a gonadotroph adenoma secreting FSH, presented with ovarian hyperstimulation, without elevation of serum estradiol. She presented with abdominal pain and large ovaries (both 10 cm in diameter) with multiple follicular cysts shortly after discontinuing oral contraceptive pills. She had a supranormal PRL level of 71 microg/liter (normal, <20), FSH of 8.4-9.2 IU/liter (normal for follicular phase, 2.4-10), LH of 0.01 IU/liter (normal, 1.6-9.3), estradiol of 108 pmol/liter (normal for follicular phase, 80-790), and free alpha-subunit level of 0.11 microg/liter (normal, <1.8). A nuclear magnetic resonance study revealed invasive pituitary macroadenoma, 30 mm in diameter. Dopamine agonist (cabergoline) treatment normalized serum PRL but had no affect on FSH levels. A transsphenoidal surgery was performed, and most of the adenoma was resected. One month after surgery the patient resumed menstruation, and the hormonal profile included serum FSH of 6.3 IU/liter, LH of 2.1 IU/liter, estradiol of 156 pmol/liter, and PRL of 10 microg/liter. The excised adenoma tissue exhibited intense immunostaining for FSH and secreted this hormone to culture medium. Stimulation with TRH (both in vivo preoperatively and in vitro study of the excised tumor) had no effect on FSH secretion from the adenoma. Estradiol did not suppress FSH release from cultured adenoma cells. Patient serum samples showed significant FSH bioactivity when tested in a human granulosa cell line. This case is remarkable because the ovarian hyperstimulation related to the FSH-secreting adenoma was not associated with high levels of serum estradiol, probably due to insufficient LH production by the normal pituitary. Thus, it supports the two-cell, two-gonadotropin theory, that both FSH and LH are necessary for normal ovarian estrogen production.