PITUITARY AND PERIPHERAL RESISTANCE TO THYROID HORMONE

A 32-year-old Caucasian male, clinically euthyroid, with paranoid schizophrenia and granulocytopenia, had elevated total and free serum T4 and T3; serum TSH was normal (2.7 +/- 0.7 micronU/ml). There was no goitre present, no evidence of Graves' disease, and no evidence of pituitary tumour. He had a normal response to methyl-TRH, with a TSH increment of 14.6 micronU/ml, T3 increment of 212 ng/dl, and T4 increment of 4.7 microgram/dl; baseline value and decreased the TSH increment in response to methyl-TRH. T3 therapy (100 microgram/day) decreased the thyroidal radioactive iodine uptake to less than half the baseline prolactin was normal with a normal response to methyl-TRH to 4.1 micronU/ml. Iodine therapy caused an increase in his baseline TSH with an increase in the TSH response to TSH. The metabolic clearance rates (MCR) and production rates (PR) of T3 and T4 were increased. Baseline serum levels of glycoprotein hormone alpha-subunit were normal and showed a slight increase in response to methyl-TRH, similar to normal subjects. This patient has evidence of partial pituitary and peripheral resistance to thyroid hormone; his only evidence for hyperthyroidism is the elevated MCR and PR of T3 and T4.     

Influence of methyl-TRH-induced prolactin increase on serum testosterone levels in normal adult men.

Our previous studies suggest that increased serum PRL, secondary to haloperidol-induced dopamine blockade, augments serum testosterone (T) levels in normal men. To rule out a direct effect of haloperidol on the testis, serum samples from a methyl-TRH study in normal men, in whom serum PRL levels were increased by a stimulus other than dopamine blockade, were analyzed for T. Fourteen subjects received both a low dose (6.25-12.5 micrograms) and a high dose (100-500 micrograms) of methyl-TRH on separate days; blood sampling was done for 15 min before and for 4 h after drug infusion. Compared to a saline control group of 14 normal men, who showed a diurnal decline of serum T levels, the methyl-TRH treated subjects had statistically significant increases in serum T after both low and high doses. These data provide further support for the concept that PRL is a pituitary hormone capable of augmenting serum T levels in normal adult men.     

Effect of prolonged oral administration of TRH on plasma levels of thyrotrophin and prolactin in normal individuals and in patients with primary hypothyroidism.

Forty mg TRH/day was given orally for 3 weeks to 10 euthyroid women and 10 women with primary hypothyroidism on low replacement doses of thyroxine. Once weekly oral TRH was replaced by an iv TRH-test (0.4 mg) with measurement of serum concentration of TSH, prolactin (PRL), thyroxine (T4), triiodothyronine (T3) and cholesterol. In the normal group, mean serum T4 concentration increased after one week and remained elevated. Serum TSH concentration showed a slight tendency to decline. Maximal rise in TSH concentration after iv TRH (deltaTSH) fell from a mean of 4.0 ng/ml to 1.4 ng/ml within one week and stayed low. T3, cholesterol, PRL and deltaprl were normal and unchanged throughout. In the hypothyroid group T4, T3, cholesterol, PRL and deltaPRL were not influenced by the TRH administration. In 2 patients (with the highest serum T4 concentrations) serum TSH concentration was normal and resistant to iv TRH. Of the 8 patients with elevated TSH, basal level and deltaTSH did not change in 2 (with subnormal T4 levels and the highest TSH levels). In the other 6 (with intermediate T4 levels) basal TSH fell from a mean of 10.1 ng/ml to 4.2 ng/ml, and deltaTSH from 10.0 ng/ml to 3.3 ng/ml after three weeks. It is concluded that in addition to feed-back effect of thyroid hormones, the pituitary response to long-term administration of TRH is determined by other factors. Among these may be reduced pituitary TRH receptor capacity and the activity of the TSH producing cells.     

Induction of hypothyroidism and hypoprolactinemia by growth hormone producing rat pituitary tumors.

The GH3 rat pituitary tumor cell line which secretes both growth hormone (GH) and prolactin (PRL) stopped releasing PRL when transplanted to animals; furthermore, it suppressed PRL production by the hosts' pituitary glands. When the same tumor was transferred back to cell culture, PRL production resumed. The PRL to GH ratio in cell culture medium and cells ranged from 5 to 1 while in the tumor and serum of the host animals it averaged 0.09 and 0.001, respectively. To investigate further this phenomenon, female rats were transplanted with GH3 tumors (T) and compared to intact normal (N) and to thyroidectomized (Tx) rats. T animals were larger and had splanchnomegaly but smaller pituitaries and thyroids. Serum PRL concentrations in the basal state were decreased, as were levels of triiodothyronine (T3), thyroxine (T4), and free T4 index. Despite reduced serum thyroid hormone concentrations, and in contrast to Tx animals, the serum thyrotropin (TSH) level in T rats was not elevated and they did not show a supranormal TSH response to thyrotropin-releasing hormone (TRH) administration. The PRL response to TRH in T animals was completely abolished while all N and Tx animals responded by a significant increase in serum PRL. Serum corticosteroids and estrogens were normal in T rats. Pituitary content of PRL was decreased and that of TSH increased in T rats. Tx animals, however, had a reduced pituitary content of PRL, TSH, and GH. When GH3 cells were grown in cell culture media containing serum from T animals, there was a reduction of PRL content in cells and released in the medium. Addition of T3 to the T serum did not alter its suppressive effect on PRL nor did rat GH added to N serum alter PRL production and release in vitro. In a preliminary experiment, rats injected ip with 50 mug hGH in two divided doses for eighteen days, suppressed serum T4 and T3 concentrations; pituitary content of TSH was significantly increased and that of PRL slightly decreased. Injection with 250 mug oPRL or saline, on the same schedule and for the same length of time, had no significant effect on the levels of serum thyroid hormones. Thus, GH, but also possibly other substance(s) secreted by GH3 tumors in vivo a) suppress the production of tumor and pituitary PRL; b) suppress the release of TSH, causing mild hypothyroidism; c) inhibit the PRL and TSH responses to TRH; and d) decrease the production of PRL in tissue culture. Although no simple and unifying theory could explain these findings, an hypothesis implicating somatomedin is presented.     

Thyrotropin-releasing hormone stimulates growth hormone release from the anterior pituitary of hypothyroid rats in vitro

We have examined the interaction of thyroid hormone and TRH on GH release from rat pituitary monolayer cultures and perifused rat pituitary fragments. TRH (10(-9) and 10(-8)M) consistently stimulated the release of TSH and PRL, but not GH, in pituitary cell cultures of euthyroid male rats. Basal and TRH-stimulated TSH secretion were significantly increased in cells from thyroidectomized rats cultured in medium supplemented with hypothyroid serum, and a dose-related stimulation of GH release by 10(-9)-10(-8) M TRH was observed. The minimum duration of hypothyroidism required to demonstrate the onset of this GH stimulatory effect of TRH was 4 weeks, a period significantly longer than that required to cause intracellular GH depletion, decreased basal secretion of GH, elevated serum TSH, or increased basal secretion of TSH by cultured cells. In vivo T4 replacement of hypothyroid rats (20 micrograms/kg, ip, daily for 4 days) restored serum TSH, intracellular GH, and basal secretion of GH and TSH to normal levels, but suppressed only slightly the stimulatory effect of TRH on GH release. The GH response to TRH was maintained for up to 10 days of T4 replacement. In vitro addition of T3 (10(-6) M) during the 4-day primary culture period significantly stimulated basal GH release, but did not affect the GH response to TRH. A GH stimulatory effect of TRH was also demonstrated in cultured adenohypophyseal cells from rats rendered hypothyroid by oral administration of methimazole for 6 weeks. TRH stimulated GH secretion in perifused [3H]leucine-prelabeled anterior pituitary fragments from euthyroid rats. A 15-min pulse of 10(-8) M TRH stimulated the release of both immunoprecipitable [3H]rat GH and [3H]rat PRL. The GH release response was markedly enhanced in pituitary fragments from hypothyroid rats, and this enhanced response was significantly suppressed by T4 replacement for 4 days. The PRL response to TRH was enhanced to a lesser extent by thyroidectomy and was not affected by T4 replacement. These data suggest the existence of TRH receptors on somatotrophs which are suppressed by normal amounts of thyroid hormones and may provide an explanation for the TRH-stimulated GH secretion observed clinically in primary hypothyroidism.     

Serum thyrotropin and prolactin in the syndrome of generalized resistance to thyroid hormone: responses to thyrotropin-releasing hormone stimulation and short term triiodothyronine suppression

Serum TSH and PRL levels and their response to TRH were measured in 11 patients with generalized resistance to thyroid hormone (GRTH), 6 euthyroid subjects, and 6 patients with primary hypothyroidism. TSH and PRL levels and their response to TRH were also measured after the consecutive administration of 50, 100, and 200 micrograms T3 daily, each for a period of 3 days. Using a sensitive TSH assay, all GRTH patients had TSH values that were elevated or within the normal range. On the basis of a normal or elevated TSH level, GRTH patients were classified as GRTH-N1 TSH (5 patients) or GRTH-Hi TSH (6 patients), respectively. Only GRTH patients with previous thyroid ablative therapy had basal TSH values greater than 20 mU/L. TSH responses, in terms of percent increment above baseline, were appropriate for the basal TSH level in all subjects. No GRTH patient had an elevated basal PRL level. PRL responses to TRH were significantly increased only in the hypothyroid controls compared to values in all other groups. On 50 micrograms T3, 7 of 12 (58%) nonresistant (euthyroid and hypothyroid) and 1 of 11 (9%) resistant subjects had a greater than 75% suppression of the TSH response to TRH. On the same T3 dose, 2 of 12 (17%) nonresistant and 4 of 11 (36%) resistant subjects had a greater than 50% suppression of the PRL response to TRH. On 200 micrograms T3, all subjects, except for 1 with GRTH, had a greater than 75% suppression of the TSH response to TRH. On the same T3 dose, while 11 of 12 (92%) nonresistant subjects had a greater than 50% reduction of the PRL response to TRH, only 3 of 10 (30%) resistant patients showed this degree of suppression (P less than 0.005). Without previous ablative therapy, serum TSH in patients with GRTH is usually normal or mildly elevated. The TSH response to TRH is proportional to the basal TSH level and is suppressed by exogenous T3. However, on 200 micrograms T3 basal TSH was not detectable (less than 0.1 mU/L) in all euthyroid subjects, but it was measurable in three of four GRTH patients with normal TSH levels before T3 treatment. PRL levels in GRTH are normal even when TSH is elevated. The PRL response to TRH is not increased in GRTH. In all subjects, exogenous T3 suppresses the PRL response to TRH to a lesser degree than the TSH response, but this difference is much greater in patients with GRTH.     

The influence of long-term low dose thyrotropin-releasing hormone infusions on serum thyrotropin and prolactin concentrations in man

The purpose of the present study was to evaluate in man the relative thyrotroph and lactotroph response to a 48-h low dose constant TRH infusion. Before, during, and after the 75 ng/min TRH constant infusion, serum samples were obtained every 4 h in six euthyroid ambulating male subjects for measurements of TSH, PRL, T4, and T3. The TSH response, employing a specific and sensitive human TSH RIA, demonstrated a significant rise from the mean basal pre-TRH value of 2.35 +/- 0.64 microU/ml (+/- SEM) to 3.68 +/- 0.80 (P < 0.005) during the TRH infusion; this value fell below the basal level to 1.79 +/- 0.47 (P < 0.05) post infusion. Serum T4 values were increased above basal both during (P < 0.025) and after (P < 0.025) TRH infusion, whereas serum T3 values were not significantly changed throughout the entire study period. The daily TSH nocturnal surge was augmented in both absolute and relative terms during the first 24 h or the TRH infusion, unchanged during the second 24 h of infusion, and inhibited during the first postinfusion day. Other than a minimal increase in serum PRL during the first few hours of the infusion, no significant alteration in the mean basal concentration or circadian pattern of PRL secretion was evident during or after the low dose TRH infusion. These findings would indicate that 1) near-physiological stimulation of the pituitary with TRH produces a greater stimulation of TSH release than of PRL release and 2) the factor or factors producing the circadian TSH surge may not be mediated through fluctuations in endogenous TRH.     

The Effect of Long-Term Cimetidine Treatment on PRL and TSH Response Capacity to TRH in Male Patients with Duodenal Ulcer

ABSTRACT. The effect of long-term cimetidine treatment for 6 months on basal and thyrotropin-releasing hormone (TRH)-stimulated prolactin (PRL) and thyroid-stimulating hormone (TSH) secretion was studied in eight male patients with duodenal ulcer. They received 1000 mg cimetidine orally per day until ulcer healing and thereafter 400 mg daily for the remaining period. TRH perturbation tests were performed before and after the 6 months of treatment. A significant reduction in the pituitary TSH response capacity was found. No significant changes in basal and TRH-stimulated PRL, basal TSH, thyroxine and triiodothyronine were found. It is uncertain if the reduction in pituitary TSH response capacity has any clinical implications in euthyroid patients.     

PITUITARY MICROADENOMA: DIAGNOSTIC STUDIES

Forty-one women with oligo-menorrhoea and/or galactorrhoea were subjected to hypothalamic pituitary-thyroid testing in an attempt to establish the presence or absence of an underlying pituitary microadenoma. They were divided into two groups in accordance with the serum level of prolactin (PRL): Group I (N = 25, mean +/- SE 17.6 +/- 1.5 ng/ml) and Group II (N = 16, 102.8 +/- 29.7 ng/ml). The dynamic tests performed were a TRH test, a stimulation test with metoclopramide (MCP) and a suppression test with bromocriptine. The results of these tests were compared with those obtained in nine normal women and eleven patients with surgically proved pituitary microadenoma. Radiologically abnormal pituitary fossas were found in ten subjects from Group I and in fourteen from Group II. All patients were euthyroid. A persistently elevated serum TSH in response to TRH was observed in patients of Group II suggesting an hypothalamic abnormality and a progressive decrease in the 120-min use of serum T3 was noted with increasing evidence of the existence of a pituitary tumour. A negative correlation was found between the basal serum PRL and the rise of serum PRL with TRH. Patients from Group II showed a lower PRL response to MCP when compared to Group I and again a negative correlation between basal level of serum PRL and the change after MCP was observed. No clear difference in the 4-h response to bromocriptine was found between the different groups of subjects. In conclusion, none of the three tests analysed permitted us to establish which of the patients had an underlying pituitary microadenoma.     

Evaluation of dopaminergic tone in hyperprolactinemia. III. Thyroid-stimulating hormone response to metoclopramide in differential diagnosis and postoperative follow-up of prolactinoma patients

Recently, it has been shown that patients with a PRL-secreting pituitary adenoma have a greater thyroid stimulating hormone (TSH) release after dopamine (DA)-receptor blockade than normal subjects. We have compared the TSH and PRL responses to metoclopramide (MCP) in normal and postpartum lactating women with those in 28 patients with hyperprolactinemia of different origin. Patients with a PRL-secreting pituitary adenoma were also tested after transsphenoidal removal of the tumor in order to establish the prognostic value of this test in such patients. Following MCP administration, percent increases in plasma PRL levels were greater in normal female subjects than postpartum lactating women. Plasma TSH levels did not increase in postpartum women and had a modest increment in normal subjects. In patients with hypothalamic tumors and empty sella syndrome plasma PRL and TSH levels showed modest or no increases after MCP administration. In ten patients harboring a microprolactinoma, plasma TSH levels showed an exaggerated increment after DA-receptor blockade. Postoperatively, despite normal or borderline PRL levels in the immediate postoperative period, a TSH response to MCP was present (in five patients one to two weeks after the operation, and in five patients one to three years after the operation), suggesting an increased DA activity even in the absence of hyperprolactinemia. In conclusion, the TSH test can easily detect increased DA-activity in patients with a microprolactinoma both preoperatively and postoperatively. It is possible that some patients with increased DA-activity in presence of normal PRL levels and normal PRL responsiveness to stimulation will experience a recurrence of hyperprolactinemia.(ABSTRACT TRUNCATED AT 250 WORDS)     

The effects of pyridoxine on pituitary hormone secretion in amenorrhea-galactorrhea syndromes

Six patients with amenorrhea, five of whom had galactorrhea and elevated PRL levels, were evaluated on a metabolic ward. All had normal sella tomograms, normal thyroid functions, and routine laboratory evaluations. None of the patients had taken any medication in the previous 6 months. On alternate days, five patients received 500 microgram of TRH iv with the measurement of PRL, TSH, FSh, LH, and hGH; 500 mg L-dopa orally with the measurement of PRL, FSH, and LH; a bolus infusion of 300 mg pyridoxine (B6) with measurement of PRL, hGH, TSH, FSH, and LH; and 25 mg chlorpromazine (CPZ) im with the measurement of PRL, LH, and FSH. The patients were then discharged on 600 mg oral pyridoxine/day and were readmitted for a repeat of the complete protocol 21 days later. The patients were continued on 600 mg oral pyridoxine for 3-4 months with monthly evaluations of serum PRL, LH, and FSH levels. These evaluations continued for 3 months after discontinuing pyridoxine. There was no demonstrable change in serum PRL after acute or chronic B6 therapy, mor was there a significant change in the response of PRL to CPZ, L-dopa, or TRH. The mean basal PRL was 97.5 +/- 9.7 ng/ml and after 3-4 months of oral pyridoxine was 97.1 +/- 14.8. In addition, there was no significant change in LH or FSH levels in response to acute or chronic B6, TRH, L-dopa, or CPZ. Neither acute B6 infusion nor chronic B6 therapy had any effect on TSH or the TSH response to TRH. Finally, acute B6 infusion had no effect on hGH levels and there were no paradoxical hGH responses to TRH. Two patients began having regular menses while on chronic pyridoxine. Their hormonal responses did not differ from those of the group, however.     

Serum prolactin in patients with "functionless" chromophobe adenomas before and after therapy.

The immunoreactive serum human prolactin (PRL) level was measured before and after intravenous administration of 500 mug of thyrotrophin-releasing hormone (TRH) in 11 patients with "functionless" chromophobe adenomas before and after surgery and after radiotherapy in 6 of these patients. The results were compared to other pituitary function tests. Two of the patients studied had recurrent disease after previous pituitary surgery and radiotherapy. Five patients had pituitary surgery through the transfrontal route, while 6 had adenoma removal via the transnasal transsplenoidal route. Before surgery, the serum PRL concentration was abnormally high in 4 patients, before and after TRH administration. It was normal in 6 and subnormal in 1 patient who had had previous therapy. Two of the patients studied showed high serum thyroid-stimulating hormone (TSH) levels in the presence of low serum T3 and T4 suggesting primary hypothyroidism with a secondary TSH-producing pituitary tumour. After surgery all patients showed a significant decrease of the serum PRL level. This contrasts with more variable results in the measurements of other pituitary hormones. Post-operative radiotherapy produced no significant additional change in serum PRL levels in 5 of the 6 patients measured 6 months to 4 years after radiotherapy. Five of the 6 patients who had adenoma removed via the transsphenoidal route required no cortisol replacement and 4 remained euthyroid, whereas all 5 patients after transfrontal surgery required both cortisol and thyroid hormone replacement. These results indicate: (1) that measurement of serum PRL levels at basal and after TRH administration in patients with "functionless" chromophobe adenomas before and after treatment may be the best index for evaluating the effect of therapy; (2) that adenoma removal may be followed by preservation of normal pituitary function, but this is more likely to occur if the transsphenoidal approach is used; and (3) that primary thyroid insufficiency may be associated with a pituitary adenoma.     

Clinical assessment of posterior pituitary function by direct measurement of plasma vasopressin levels during hypertonic saline infusion

Clinical usefulness of a radioimmunoassay of plasma arginine vasopressin concentration (AVP) during hypertonic saline infusion for the assessment of posterior pituitary function was studied in comparison with the conventional water deprivation test. Infusion of 5% saline at a rate of 0.05 ml/kg/min for 120 min in 15 normal subjects induced an elevation of plasma osmolality (Posm) from 290.3 +/- 0.7 to 307.5 +/- 2.1 mOsm/kg with a resultant increase in AVP from 2.4 +/- 0.4 to 9.9 +/- 2.2 pg/ml. During the infusion, a highly significant correlation between AVP and Posm was observed with a regression line expressed as AVP = 0.40 (Posm - 283.0). In 22 polyuric patients, on the other hand, the infusion induced a marked elevation of Posm from 302.6 +/- 2.5 to 321.3 +/- 2.9 mOsm/kg, but caused a slight (less than 5.8 pg/ml) or no increase in AVP from the basal levels (0.5 +/- 0.1 pg/ml). A conventional water deprivation test was carried out in ten patients with neurogenic diabetes insipidus, including one who had coincidental nephrogenic diabetes insipidus. As would be expected, urine osmolality (Uosm) did not rise beyond Posm in seven of them. However, two of three other patients, who had a complete lack of AVP response to the hypertonic saline, were able to concentrate their urine with a maximal Uosm/Posm of 1.3 and 1.1 respectively. The concurrent decrease in creatinine clearance to 49 and 57% of the initial values, respectively, indicated that a marked reduction in glomerular filtration rate due to severe dehydration was responsible for the unexpected concentration of urine in the patients with totally impaired AVP secretion. Based on these results, we conclude that the direct measurement of AVP during hypertonic saline infusion is an essential procedure for the accurate evaluation of posterior pituitary function.     

Reversible hypopituitarism in patients with large nonfunctioning pituitary adenomas

Detailed pituitary function studies were conducted on 26 patients with large nonfunctioning pituitary adenomas before and 2-3 months after transsphenoidal adenomectomy. Basal serum PRL, GH, TSH, LH, FSH, and ACTH levels were measured, and dynamic studies of their secretion were made. Preoperatively, GH deficiency was found in all 26 patients (100%), hypogonadism in 25 patients (96%), hypothyroidism in 21 patients (81%), and adrenal insufficiency in 16 patients (62%). Serum PRL levels were low (1.5-4 ng/ml) in 5 patients, normal (5-20 ng/ml) in 9 patients, and mildly elevated (21-53 ng/ml) in the remaining 12 patients. After selective adenomectomy, variable improvement in pituitary function occurred in 17 patients, worsening in 1 patient, and persistence of hypopituitarism in 8 patients. After surgery, normal thyroid function was documented in 12 of the 21 patients (57%) who were hypothyroid preoperatively. Similarly, 6 of the 16 patients (38%) with adrenal insufficiency recovered normal adrenal function, and 8 of the 25 patients (32%) with hypogonadism recovered normal gonadal function. GH deficiency persisted in all but 4 patients (15%). Serum PRL levels decreased in all patients, and only 5 had midly elevated levels after surgery. The presence of a normal or mildly elevated serum PRL level before surgery in these patients was of value in predicting possible recovery of pituitary function after surgery; none of the 5 patients with low preoperative serum PRL levels had any improvement in pituitary function after surgery. A rise in serum TSH levels after TRH administration before surgery also was helpful in predicting possible recovery from hypopituitarism. Most patients who had a rise in serum TSH level in response to TRH stimulation preoperatively recovered some pituitary function after adenomectomy. In contrast, no improvement in pituitary function occurred in patients who had blunted responses to TRH preoperatively. Improvement in pituitary function occurred more often in patients with tumors measuring 25 mm or less than in those with larger tumors. In conclusion, significant improvement in pituitary function may occur after surgical adenomectomy for nonsecreting pituitary tumors. A rise in serum TSH levels in response to TRH stimulation preoperatively suggested the presence of viable pituitary tissue in these patients with hypopituitarism. The presence of a normal or mildly elevated serum PRL level before surgery also suggested the presence of functioning pituitary lactotrophs. These observations suggest that compression of the portal circulation is a possible mechanism for hypopituitarism in this setting.(ABSTRACT TRUNCATED AT 400 WORDS)     

The inability of dynamic tests of prolactin and TSH secretion to differentiate between tumorous and non-tumorous hyperprolactinemia

Certain hyperprolactinemic patients have an obvious pituitary tumor while others with normal pituitary radiology may or may not harbor a pituitary microadenoma. A variety of biochemical tests have been proposed to distinguish between those with and those without pituitary tumors. The aims of this study were: firstly to examine these tests to assess their efficacy in differentiating between patients with radiologically-demonstrated pituitary tumors and normal controls; and secondly to establish if those hyperprolactinemic patients with normal radiology formed two distinct groups biochemically as might be expected if some did and some did not have tumors. The prolactin (PRL) and thyroid stimulating hormone (TSH) response to domperidone and the PRL response to TRH and insulin-induced hypoglycemia have thus been examined in hyperprolactinemic subjects with and without radiological evidence of an adenoma and in normal controls. The basal serum PRL was similar in patients with and without radiological evidence of a pituitary adenoma. The serum PRL response to all stimuli studied, expressed as a percentage of initial values, was blunted in patients with known pituitary tumors with total separation from values in control subjects. Results for patients with normal pituitary radiology were similar to those for patients with tumors with minimal overlap with controls. The peak TSH increment after domperidone was exaggerated in patients with known tumors, but overlap with control values was observed in 25%. In patients with normal radiology the peak TSH increment after domperidone was similarly increased but again overlap with control values occurred in 28%. Cluster analysis showed no evidence of two subgroups of response with in the hyperprolactinemic patients.(ABSTRACT TRUNCATED AT 250 WORDS)     

Normal pituitary function and reserve after selective transsphenoidal removal of a thyrotropin-producing pituitary adenoma

A 37-yr-old woman with recurrent hyperthyroidism after partial thyroid ablation was found to have an enlarged sella turcica and elevated serum thyrotropin (TSH) and prolactin (PRL) levels measured by radioimmunoassay. Serum growth hormone (GH), luteinizing hormone (LH), follicle-stimulating hormone (FSH), and cortisol levels were within normal limits and responded appropriately to provocative stimuli both before and after surgery. Preoperatively, the administration of thyrotropin-releasing hormone (TRH) (200 μg i.v.) and metoclopramide (MCP) (10 mg p.o.) induced a more than twofold increase in serum PRL levels, whereas TSH was only modestly affected. Bromocriptine (2.5 mg p.o.) and l-dopa (500 mg p.o.) suppressed TSH and PRL values to less than 50% of their initial values. After selective transsphenoidal removal of a pituitary adenoma, signs and symptoms of hyperthyroidism disappeared and TSH and PRL returned to normal. The postoperative administration of TRH and MCP produced a normal response for both PRL and TSH. Postoperatively, bromocriptine induced a parallel decrease in the serum level of both hormones, whereas l-dopa decreased PRL but had no effect on the serum TSH level. This case provides evidence that hyperthyroidism caused by a pituitary adenoma can be successfully treated by transsphenoidal surgery with preservation of normal pituitary function and reserve.     

Divergent influences of calcium ions on releasing factor-stimulated anterior pituitary hormone secretion in normal man

To investigate the influence of calcium ions on the secretion of anterior pituitary hormones in response to stimulation by exogenous hypothalmic releasing factors in man, we measured serum concentrations of pituitary hormones serially during a continuous infusion of combined TRH (2 micrograms/min) and GnRH (1 microgram/min), with concomitant iv saline or calcium administration. Compared to saline, calcium administration was associated with a significant increase in GnRH-TRH-stimulated LH and FSH release and a corresponding rise in serum testosterone concentrations. The effect of calcium ions on gonadotropin secretion was specific, because releasing factor-stimulated secretion of TSH and PRL was suppressed by hypercalcemia. Serum concentrations of GH were not significantly altered under these conditions. In summary, the present results provide the first in vivo evidence that acute infusion of calcium ions augments GnRH-TRH-stimulated secretion of LH and FSH, with an accompanying increase in serum testosterone levels. In contrast, hypercalcemia did not alter serum GH concentrations, and it suppressed GnRH-TRH-stimulated release of PRL and TSH. We conclude that calcium ions can selectively influence releasing factor-stimulated secretion of certain anterior pituitary hormones in man.     

Thyroid-stimulating hormone and prolactin levels in breast cancer.

Serum thyroid-stimulating hormone (TSH) and prolactin (PRL) levels were measured before and after intravenous administration of protirelin to 148 patients with breast carcinoma. There was a high prevalence (36%) of elevated basal TSH; however, most of the patients were euthyroid and had normal serum thyroxine and T3 resin uptake. The PRL level was elevated in 22% of the cases. Both the mean PRL and the mean TSH levels for the breast cancer patients were significantly elevated above the respective means in a control group. We could find no correlation between serum TSH and PRL levels, suggesting that the purported association between a decreased thyroid state and breast cancer is probably not mediated through an increased PRL level. The mean survival and mean disease-free interval were shorter for patients with either elevated TSH or elevated PRL levels, but in neither case was the difference statistically significant.     

Multiple abnormalities of anterior pituitary hormone secretion in association with pseudohypoparathyroidism

A male with pseudohypoparathyroidism presented with several hormonal abnormalities. He was clinically euthyroid with no palpable goiter, His serum T4, total T3, T3 Sephadex retention, and 131I uptake were normal. However, elevated basal TSH levels and exaggerated TSH responses to TRH which normalized during the administration of thyroid extract suggested reduced thyroidal reserve. Despite these finding the 131I uptake increased after exogeneous TSH, and the T3 level rose after TRH. Basal testosterone levels and response to hCG were normal however, gonadotropins were elevated and there was an exaggerated response after LRH treatment. Both LH and FSH levels were suppressed by testosterone propionate. The patient demonstrated intermittent basal hyperprolactinemia and impaired PRL responsiveness after metolopramide, chlorpromazine, and insulin administration. There was, however, an intact response to TRH. Basal PRL, TSH, and LH levels decreased after the administration of L-dopa and bromocriptine. Although the precise mechanism underlying these finding is unknown, the elevated basal levels of TSH, LH, and FSH and the exaggerated responses to their respective releasing hormones suggest the presence of partial degree of end-organ resistance to these pituitary trophic hormones. Together with the resistance to PTH, this may imply a common defect, presumably at a postreceptor level. However, hyporesponsiveness of PRL to metoclopramide and chlorpromazine and normal responsiveness to TRH suggest that an abnormality of dopamine tone also exists in pseudohypoparathyroidism.     

Effect of Synthetic Thyrotrophin Releasing Hormone (TRH) in Man

Summary: Synthetic TRH (200 μ g) administered intravenously to twelve normal subjects produced a consistent rise in serum thyrotrophin (TSH) levels reaching a peak 20 – 30 mins following the injection. No reproducible effects were seen on plasma levels of GH, LH, FSH or 11 -hydroxycorticoids measured concomitantly with TSH. Mean free thyroxine index following TRH rose by 23% at 60 and 120 mins. Two subjects treated with triiodothyronine and 17 untreated thyrotoxic patients showed marked impairment of TSH response to TRH. Reduced or absent TSH responses were likewise observed in five euthyroid patients with Graves' disease, two with ophthalmopathy as the sole manifestation of the disease. In ten patients with primary hypothyroidism, synthetic TRH evoked further increases of elevated basal TSH levels with exaggerated over-all responses. Five of seven euthyroid patients with pituitary tumours showed blunted TSH responses whereas all six patients with secondary hypothyroidism (resulting from pituitary or suspected hypothalamic lesions) exhibited normal or slightly exaggerated responses.
It is concluded that synthetic TRH is a specific stimulus to pituitary TSH release with considerable potential in the diagnosis of mind disturbances of thyroid function. Its use should promote better understanding of hydothalamic-pituitary-thyroid relationships.