Impaired glucose tolerance coincides with abnormal release of growth hormone following a glucose load as well as in response to TRH in acromegaly

It is known that some acromegalic patients exhibited a paradoxical release of growth hormone (GH) after glucose administration. We have attempted to investigate a relationship between the paradoxical GH secretion with the abnormal glucose tolerance test present in some cases of acromegaly. We also studied the inappropriate increase in GH levels following thyrotropin releasing hormone (TRH) injection which is present in some acromegalics. We found that only those patients who had an abnormal glucose tolerance test exhibited simultaneously, the paradoxical release of GH, moreover, the same patients showed GH release following TRH administration. This observation suggests that some acromegalics have an abnormality in their hypothalamic glucose receptor and such abnormality is associated with abnormal GH secretion when TRH is administered. On basis of these findings it is suggested that the hypothalamus may play an important role in the pathogenesis of acromegaly in these cases.     

Effects of pirenzepine, bromocriptine and their association on basal and GHRH- and TRH-induced GH secretion in acromegaly.

In order to ascertain if pirenzepine (Pz), an antimuscarinic drug, could inhibit GH secretion in acromegaly, 8 patients were submitted to 3 successive treatment courses of 9 days each: Pz, bromocriptine (BRC) and Pz plus BRC. No change in basal levels of GH after Pz administration was seen, but its reduction (p less than 0.05) by BRC was observed. Pz plus BRC did not improve this response. None of these drugs abolished the paradoxical GH response to TRH. In 7 normal controls, Pz suppressed the GH responsiveness to GHRH (p less than 0.001), but not in acromegalic patients. BRC, instead, blunted this response. In conclusion, cholinergic control of GH secretion is altered in acromegaly. Pz, either when administered alone or associated with BRC, is not useful for the treatment of this disease.     

Comparative in vivo and in vitro studies on abnormal GH secretion in patients with acromegaly

Eight patients with active acromegaly due to GH-producing pituitary adenoma were studied. GH secretory dynamics in vitro was evaluated by adding GRF, CRF, or a somatostatin analog, SMS 201-995 to the perifusate of dispersed cells from tumors. A comparison was made between the data obtained in preoperative tests for GH secretion and those obtained in experiments in vitro. Before operation, the GRF test (100 micrograms, iv) resulted in no GH response in three of six patients examined. The CRF test (100 micrograms, iv) resulted in a paradoxical GH increase in two of the same six patients. In vitro studies performed on adenoma cells revealed that exposure to GRF (100 ng/ml) elicited an increase in GH in seven of eight patients examined. Exposure to CRF (100 ng/ml) caused an enhanced GH secretion in four of the same eight patients. There were cases in which GH response to these hypothalamic hormones was observed in vitro but not in vivo, whereas there was only one case in which CRF caused an increase in GH in vivo but not in vitro. Thus, GH secretory dynamics was not always the same in vivo and in vitro. The discrepancy could be ascribed to the different secretory status of hypothalamic hormone (e.g., GRF or somatostatin) in vivo in each acromegalic patient.     

Ectopic growth hormone-releasing hormone (GHRH) syndrome in a case with multiple endocrine neoplasia type I

A 36-yr-old man with multiple endocrine neoplasia (MEN) type I had an ectopic growth hormone-releasing hormone (GHRH) syndrome due to a GHRH-secreting pancreatic tumor. The immunoreactive (IR)-GHRH concentration in his plasma ranged from 161 to 400 pg/ml (299 +/- 61 pg/ml, mean +/- SD; normal, 10.4 +/- 4.1 pg/ml), and a significant correlation was found between his plasma IR-GHRH and GH (r = 0.622, p less than 0.02). After removal of the pancreatic tumor, the high plasma GH concentration returned to nearly the normal range (42.2 +/- 31.3 to 9.6 +/- 3.8 ng/ml). These changes paralleled the normalization of his plasma IR-GHRH (16.1 +/- 3.8 pg/ml) and some of his symptoms related to acromegaly improved. However, plasma GH (7.7 +/- 1.3 ng/ml) and IGF-I (591 +/- 22 ng/ml) concentrations were high at 12 months after surgery, suggesting adenomatous changes in the pituitary somatotrophs. Before surgery, exogenous GHRH induced a marked increase in plasma GH, and somatostatin and its agonist (SMS201-995) completely suppressed GH secretion, but not IR-GHRH release. No pulsatile secretion of either IR-GHRH or GH was observed during sleep. An apparent increase in the plasma GH concentration was observed in response to administration of TRH, glucose, arginine or insulin, while plasma IR-GHRH did not show any fluctuation. However, these responses of plasma GH were reduced or no longer observed one month and one year after surgery. These results indicate that 1) a moderate increase in circulating GHRH due to ectopic secretion from a pancreatic tumor stimulated GH secretion resulting in acromegaly, and evoked GH responses to various provocative tests indistinguishable from those in patients with classical acromegaly, and 2) the ectopic secretion of GHRH may play an etiological role in the pituitary lesion of this patient with MEN type I.     

Insulin hypoglycemia test and releasing hormone (corticotropin-releasing hormone and growth hormone-releasing hormone) stimulation in patients with pituitary failure of different origin

To investigate the efficacy of endocrine evaluation in diagnosing and localizing the cause of anterior pituitary failure, 17 patients with suprasellar space-occupying lesions, 4 patients with intrasellar tumors, 8 patients with no detectable anatomical lesion, 1 patient with posttraumatic failure and 1 patient with septooptical dysplasia were investigated. Endocrine evaluation consisted of measuring adrenocorticotropic hormone (ACTH), cortisol, and growth hormone (GH) levels during insulin hypoglycemia test (IHT) and after administration of corticotropin-releasing hormone (CRH) and growth hormone-releasing hormone (GRH). In addition, basal prolactin levels, gonadal and thyroid function were evaluated. The results showed that 4 of 17 patients with suprasellar tumors had normal ACTH and GH responses during IHT and after releasing hormone (RH) administration. Five of these patients had a normal ACTH or cortisol rise but no GH response during IHT. All 5 had a normal ACTH and 3 had normal GH rise after RH. Seven patients with suprasellar tumors had no ACTH or GH response during IHT, but all had an ACTH response to CRH. Only 3 of this group had a GH response to GRH. There was one exception of a patient who showed a GH and ACTH rise during IHT but only a blunted ACTH and no GH rise after RH administration. Four patients with pituitary failure and no demonstrable lesion had an ACTH rise after CRH but no GH rise after GRH, whereas in 3 patients with isolated ACTH deficiency no ACTH rise after CRH was seen. In 4 patients with nonsecreting pituitary tumors normal ACTH responses to IHT and CRH were seen, whereas GH rose during IHT only in 1 patient.(ABSTRACT TRUNCATED AT 250 WORDS)     

Serum thyrotropin response to combined arginine and thyrotropin-releasing hormone administration provides evidence for an altered somatostatinergic tone in acromegaly.

The aim of this study was to evaluate plasma thyrotropin (TSH), prolactin (PRL) and growth hormone (GH) responses to the TSH-releasing hormone (TRH) test and to a combined arginine-TRH test (ATT-TRH) in 10 normal subjects and in 15 acromegalic patients. In controls, TSH responsiveness to TRH was enhanced by ATT (p less than 0.001). When considering the 15 acromegalic patients as a whole, no significant difference in TSH responses was detected during the two tests. However, patients without suppression of plasma GH levels after oral glucose load showed an increased TSH responsiveness to the ATT-TRH test if compared to TRH alone (p less than 0.025), while patients with partial suppression of plasma GH levels after glucose ingestion showed a decreased TSH responsiveness to ATT-TRH (p less than 0.05). No difference was recorded in PRL and GH responses, evaluated as area under the curve, during TRH or ATT-TRH tests in controls and in acromegalics. In conclusion, (1) normal subjects have an enhanced TSH response to the ATT-TRH test and (2) acromegalic patients without suppression of GH levels after oral glucose load show a TSH responsiveness to the ATT-TRH test similar to that of controls, while acromegalics with partial GH suppression after oral glucose load have a decreased TSH responsiveness to the ATT-TRH test. These data suggest that acromegaly is a heterogeneous disease as far as the somatostatinergic tone is concerned.     

Growth hormone releasing hormone-sensitive adenylate cyclase activity in growth hormone-producing pituitary adenoma: correlation to the response of plasma growth hormone to growth hormone releasing hormone in patients with acromegaly

The correlation between response of plasma GH to GHRH and the GHRH-induced stimulation of the intracellular adenylate cyclase (AC) activity in pituitary adenoma cell membranes in acromegalic patients was investigated. Each peak plasma GH level after iv administration of GHRH ranged from 1.1 to 13.8 times the basal level in 13 acromegalic patients. On the other hand, the maximal stimulation of intracellular AC activity (cAMP production) induced by GHRH varied from 1.4 to 6.4 times the control level in each GH-producing pituitary adenoma cell membrane. A significant positive correlation (r = 0.89, P less than 0.005) between plasma GH response to GHRH and intracellular cAMP production stimulated by GHRH was observed in nine of the acromegalic patients. In contrast, the response of plasma GH to GHRH was significantly blunted, despite a fairly large production of intracellular cAMP stimulated by GHRH, in the other four acromegalic patients. These results suggest that GHRH-induced GH release from GH-producing pituitary adenomas of patients with acromegaly may be regulated not only by GHRH receptor-adenylate cyclase system but also modified by several other factors including somatostatin and Sm-C.     

Clinical studies with GHRH in man

GHRH was isolated from two GHRH-secreting pancreatic tumors which resulted in clinical acromegaly. Over 98% of acromegalic patients have a pituitary adenoma; however, acromegaly may occasionally result from ectopic or eutopic GHRH secretion. Administration of GHRH to normal adults stimulates growth hormone (GH) secretion; it may also stimulate GH release in some adults with GH deficiency in childhood and in a majority of GH-deficient children. Continuous infusion of GHRH to normal men stimulates GH secretion which augments naturally occurring GH pulses. GHRH is effective when administered subcutaneously and intranasally, but requires 30- and 300-fold higher doses, respectively. Intermittent subcutaneous GHRH therapy promotes acceleration of linear growth in GH-deficient children and appears promising as a treatment for these children.     

Circulating growth hormone releasing factor concentrations in normal subjects and patients with acromegaly.

A highly specific and sensitive radioimmunoassay was developed for measuring circulating growth hormone releasing factor (GRF) in human plasma. Before measuring immunoreactive GRF plasma samples were extracted on to Vycor glass. Immunoreactive GRF concentrations in plasma samples from 37 fasting normal subjects ranged from less than 10 to 60 ng/l (mean 21 ng/l). Fasting concentrations in 76 out of 80 acromegalic subjects were within the normal range, but the remaining four patients had values of 92 to 25 000 ng/l. Of these, only the patient with the highest concentration had evidence of ectopic GRF secretion from a disseminated carcinoid tumour. Two of the others had longstanding pituitary tumours, and the fourth patient had a pituitary growth hormone (GH) secreting tumour proved by its removal and subsequent remission of acromegaly. There was no correlation between serum GH and plasma immunoreactive GRF concentrations, irrespective of whether the patients were untreated or had been given radiotherapy or dopamine agonists. The assay should help elucidate the physiological role(s) of GRF and may also prove useful in differentiating between pituitary and hypothalamic defects in patients with acromegaly.     

Acute effects of hydrocortisone on circulating growth hormone levels in patients with acromegaly.

Aim of our study was to investigate the acute effects of intravenous infusion of hydrocortisone on circulating growth hormone (GH) levels in acromegaly. We studied 5 adult patients with active acromegaly, 3 males and 2 females; age 52 +/- 3.6 years, body mass index 27 +/- 1 kg/m2. The patients underwent in randomized order from 0 to 120 min: (1) intravenous infusion of saline, 250 ml; (2) bolus intravenous injection of hydrocortisone succinate, 100 mg at time 0 followed by intravenous infusion of hydrocortisone succinate, 250 mg in 250 ml of saline for 120 min. Blood samples for GH, cortisol and glucose assay were taken at -15, 0 (time of beginning of saline or hydrocortisone infusion), 15, 30, 45, 60, 90, 120, 150 and 180 min. In all the acromegalic patients, during hydrocortisone succinate infusion, GH values clearly fell with respect to saline (nadir range 18.4-50.5% with respect to baseline levels) with nadir between 60 and 180 min after the beginning of the infusion. Our data show that acute and sustained hypercortisolism, decreases circulating GH levels in acromegaly. It seems likely that also in acromegalic patients as well as in normal subjects short-term increases in serum cortisol levels may be able to cause an enhancement of hypothalamic somatostatin secretion, which in turn may be responsible for the glucocorticoid-mediated GH inhibition.     

Effect of opiates on growth hormone secretion in acromegaly.

Morphine at doses of 5 mg and 10 mg does not stimulate growth hormone (GH) secretion in normal subjects, and its effect on GH secretion in acromegaly is not widely documented. We investigated the effect of 15 mg intravenous morphine on growth hormone in patients with active acromegaly compared to normal subjects (7 acromegalics and 5 controls). Their mean (+/- SEM) age was 30.5 +/- 7.6 years and 29.5 +/- 0.5 years, respectively. Basal and peak response of growth hormone after morphine was measured with simultaneous assay of cortisol to exclude the effect of stress. Mean (+/- SEM) basal growth hormone was 103.16 +/- 28.04 ng/ml in acromegalics compared to 4.51 +/- 1.43 ng/ml in controls. Morphine caused an elevation of growth hormone in both acromegalics and normal subjects (p < 0.05). However, the Delta (peak minus basal) response of growth hormone was comparable between the two groups. A concurrent fall in cortisol was noted after morphine in both the groups, excluding the effect of stress on growth hormone. We conclude that higher doses (15 mg) of morphine are required to stimulate GH secretion in normal subjects, and that opioids exert a positive modulating effect on growth hormone secretion in patients with active acromegaly suggesting partial autonomy of the pituitary tumor.     

Growth hormone after baclofen in normal and acromegalic subjects

Serum growth hormone (GH) levels in basal conditions (two samples) and 30, 60, 90, 120, 150 and 180 minutes after oral administration of baclofen (20 mg) were evaluated in 6 healthy subjects and in 6 acromegalic patients. The effect of cimetidine (400 mg i.v.) administrated 45 minutes after baclofen (20 mg by mouth) were evaluated in 9 healthy women. Baclofen was able to significantly rise serum GH levels in normal subjects but no in acromegalic patients. Cimetidine suppress GH increase induced by baclofen. It was concluded that: 1) baclofen, GABAb receptor agonist, stimulate GH secretion by inhibition of GIF secretion or by stimulation of GRF secretion; 2) istamine, through H2 receptors in the hypothalamus, is important to mediate GH release induced by stimulation of GABAb receptors.     

Scientific Foundations of Oncology

The effect of somatostatin on the thyrotropin (TSH), prolactin, growth hormone (GH) and insulin responses to the combined administration of thyrotropin releasing hormone (TRH) and arginine was studied in six healthy subjects, three hypothyroid patients and three acromegalic patients. Similar inhibition by somatostatin of the TSH and insulin responses was observed in the three groups. While the tetradecapeptide had no significant effect on the prolactin response in the healthy and acromegalic subjects, it caused an unexpected inhibition of the prolactin response in two of the hypothyroid subjects. Contrary to the findings in the healthy and hypothyroid subjects, somatostatin did not inhibit the GH response in the acromegalic patients. Normal inhibition by somatostatin of the insulin response, followed by a rebound in insulin secretion, was observed in all subjects. These preliminary data indicate increased sensitivity of the prolactin-secreting cells to somatostatin in hypothyroidism and suggest that decreased responsiveness of the somatotrophs to somatostatin could play a role in the pathogenesis of acromegaly.     

Normalization of thyroid stimulating hormone levels in acromegalic patients after selective adenomectomy

Changes in TSH secretion in six acromegalic patients were studied before and after transsphenoidal adenomectomy (Hardy's method) and compared to normal subjects and six patients with prolactinoma. Basal serum GH levels ranging from 5 to over 250 ng/ml before adenomectomy decreased to below 5 ng/ml after the operation, and the abnormal responses of GH to TRH observed initially in three of the six patients almost disappeared in the post-adenomectomy period. The response of serum TSH to TRH in acromegalic patients improved in each of the six patients after the operation. The TRH-stimulated TSH secretion in patients with prolactinoma of a size and grade similar to those in acromegalic patients was not so extremely low as that in the acromegalic subjects. As indicators of thyroid function, serum triiodothyronine (T3), thyroxine (T4), T3-uptake levels and free T4 indices did not change significantly after adenomectomy as compared with those before the operation in five of the six patients tested. Serum T3, T4 and T3-uptake levels and free T4 indices before adenomectomy were normal or subnormal in each patient except for a high serum T4 level and free T4 index before the operation in only one patient. Thus, it is difficult to conclude that the function of thyrotrophs was decreased by pressure upon the intact pituitary gland by the tumor, or that the thyroid gland also became hypertrophic secondary to the elevated GH, resulting in a large quantity of thyroid hormone being secreted, which caused a suppression of TSH secretion by negative feedback.(ABSTRACT TRUNCATED AT 250 WORDS)     

Growth-hormone-binding protein in patients with acromegaly.

The present study was undertaken to investigate the possible regulatory effect of chronic exposure to human growth hormone (hGH), in patients with acromegaly, on growth-hormone-binding protein (GH-BP). Nineteen patients with active acromegaly, before, during or after treatment, comprised the subjects of this study. Serum GH was measured by radioimmunoassay and GH-BP by a binding assay with dextran-coated charcoal separation. The specific binding of [125I]hGH (1 ng) obtained with 50 microliters serum was expressed as a percentage of total cpm. To evaluate the impact of the lower GH-BP on GH activity, we studied the effect of acromegalic serum on hGH displacement of [125I]hGH binding to GH receptors in rabbit liver membranes. Compared to normal controls (11.43 +/- 0.37%), the acromegalic patients had low serum levels of GH-BP (5.45 +/- 0.40%; p < 0.001), which correlated negatively with serum GH levels (p < 0.01). In 7 patients, GH-BP normalized within 2-3 months of successful therapy. The lower GH-BP was due to a reduction in binding capacity, whereas binding affinity remained unchanged. Acromegalic serum, with its low GH-BP, resulted in a shift to the left of the GH displacement curve when compared with normal human sera: IC50 values were 7.47 +/- 0.29 and 11.19 +/- 0.84 ng (p < 0.02) for acromegalic and normal human sera, respectively. We conclude that acromegaly is characterized by low levels of GH-BP due to a decrease in serum-binding capacity. The decrease in GH-BP may render the acromegalic serum GH relatively more active in the GH receptor assay.     

Pituitary surgery for the management of acromegaly

Active acromegaly is almost always the result of a benign growth hormone (GH)-secreting adenoma of the pituitary gland. Because the same pituitary stem cell can produce both GH and prolactin (PRL), many acromegalic patients also have hyperprolactinemia. The advantages of surgical excision of pituitary adenomas associated with acromegaly include: (1) prompt decrease in GH; (2) reliable and immediate relief of the mass effect from the tumor (decompression of the optic nerves and chiasm), and (3) the opportunity to obtain tumor tissue for characterization and investigative study. Currently, more than 97% of operations for removal of pituitary tumors associated with acromegaly are done using the transsphenoidal approach rather than craniotomy. Technical advances to make the surgery safer continue to evolve, and include endoscopic approaches, computer-guided image-based intraoperative visualization, and intraoperative magnetic resonance imaging. Criteria for satisfactory remission of acromegaly after surgery are the same as those used for medical management. They include normal insulin-like growth factor (IGF)-I and suppression of GH to undetectable levels (<1.0 ng/ml) during an oral glucose tolerance test (OGTT). Data from a recent series of 86 patients operated upon for acromegaly at the University of Virginia and followed for more than 1 year have been reviewed. In patients receiving surgery as the initial procedure, 67% had a normal IGF-I, and 52% suppressed to <1.0 ng/ml in an OGTT. There was one true recurrence of disease diagnosed 81 months after surgery. Results are best in patients with noninvasive microadenomas. Gamma knife radiosurgery has been a valuable adjunct in those patients who fail to achieve postoperative remission. Pathological evaluation of the tumors revealed that 16% expressed GH only, 25% stained for GH and glycoprotein hormones (follicle stimulating hormone, thyroid hormone, thyroid stimulating hormone, alpha-subunit), 21% for GH and PRL, and 33% for GH, PRL and glycoprotein hormones. There was one acidophil stem cell tumor and 10% had the mammosomatotroph subtype. This contemporary series was free of mortality or serious complications. One patient had a transient cerebrospinal fluid leak and 3 developed transient SIADH with hyponatremia. Surgical treatment remains an important aspect of the combined management of patients with acromegaly.     

Growth hormone-releasing hormone and corticotropin-releasing hormone enhance non-rapid-eye-movement sleep after sleep deprivation

The neuropeptides growth hormone (GH)-releasing hormone (GHRH) and corticotropin-releasing hormone (CRH) regulate sleep and nocturnal hormone secretion in a reciprocal fashion, at least in males. GHRH promotes sleep and GH and inhibits hypothalamo-pituitary-adrenocortical (HPA) hormones. CRH exerts opposite effects. In women, a sexual dimorphism was found because GHRH impairs sleep and stimulates HPA hormones. Sleep deprivation (SD) is the most powerful stimulus for inducing sleep. Studies in rodents show a key role of GHRH in sleep promotion after SD. The effects of GHRH and CRH on sleep-endocrine activity during the recovery night after SD are unknown. We compared sleep EEG, GH, and cortisol secretion between nights before and after 40 h of SD in 48 normal women and men aged 19-67 yr. During the recovery night, GHRH, CRH, or placebo were injected repetitively. After placebo during the recovery night, non-rapid-eye-movement sleep (NREMS) and rapid-eye-movement sleep (REMS) increased and wakefulness decreased compared with the baseline night. After GHRH, the increase of NREMS and the decrease of wakefulness were more distinct than after placebo. Also, after CRH, NREMS increased higher than after placebo, and a positive correlation was found between age and the baseline-related increase of slow-wave sleep. REMS increased after placebo and after GHRH, but not after CRH. EEG spectral analysis showed increases in the lower frequencies and decreases in the higher frequencies during NREMS after each of the treatments. Cortisol and GH did not differ between baseline and recovery nights after placebo. After GHRH, GH increased and cortisol decreased. Cortisol increased after CRH. No sex differences were found in these changes. Our data suggest that GHRH and CRH augment NREMS promotion after SD. Marked differences appear to exist in peptidergic sleep regulation between spontaneous and recovery sleep.     

TRH-Gly, a precursor of TRH, alters GH secretion in acromegaly

We explored effects of a precursor of thyrotropin (TSH)-releasing hormone (TRH), TRH-Gly, on growth hormone (GH) secretion in acromegaly. Intravenous injection of TRH-Gly produced a profound increase in GH secretion in eight, decrease in two, and no response in five out of a total fifteen patients. The magnitude of GH responsiveness to TRH-Gly was significantly correlated with that induced by TRH (r = 0.824, P less than 0.01). In contrast, TRH-Gly did not induce secretion of TSH or prolactin. The present data suggest that TRH-Gly may participate in regulating GH secretion in some patients with acromegaly and that TRH-Gly-induced GH secretion may be due at least in part to TRH-associated mechanisms underlying GH secretion.     

Role of vasoactive intestinal polypeptide (VIP) in regulating the pituitary function in man

Intramuscular injection of synthetic VIP (200 micrograms) resulted in a rapid increase in plasma prolactin (PRL) concentrations in normal women, which was accompanied by the 4- to 7-fold increase in plasma VIP levels. Mean (+/- SE) peak values of plasma PRL obtained 15 min after the injection of VIP were higher than those of saline control (28.1 +/- 6.7 ng/ml vs. 11.4 +/- 1.6 ng/ml, p less than 0.05). Plasma growth hormone (GH) and cortisol levels were not affected by VIP in normal subjects. VIP injection raised plasma PRL levels (greater than 120% of the basal value) in all of 5 patients with prolactinoma. In 3 of 8 acromegalic patients, plasma GH was increased (greater than 150% of the basal value) by VIP injection. In the in vitro experiments, VIP (10(-8), 10(-7) and 10(-6) M) stimulated PRL release in a dose-related manner from the superfused pituitary adenoma cells obtained from two patients with prolactinoma. VIP-induced GH release from the superfused pituitary adenoma cells was also shown in 5 out of 6 acromegalic patients. VIP concentrations in the CSF were increased in most patients with hyperprolactinemia and a few cases with acromegaly. These findings indicate that VIP may play a role in regulating PRL secretion in man and may affect GH secretion from pituitary adenoma in acromegaly.     

Effect of synthetic ovine corticotropin-releasing factor on growth hormone secretion in patients with acromegaly

In a significant proportion of patients with acromegaly, a non-specific increase in plasma growth hormone (GH) has been recognized following administration of thyrotropin-releasing hormone (TRH) or luteinizing hormone-releasing hormone (LH-RH), probably due to the lack of the specificity of the receptor in their tumor cells. In this study, the effects of corticotropin-releasing factor (CRF), a newly isolated hypothalamic hormone, in addition to TRH and LH-RH, on plasma levels of GH and the other anterior pituitary hormones were evaluated in 6 patients with acromegaly. Synthetic ovine CRF (1.0 microgram/kg), TRH (500 micrograms) or LH-RH (100 micrograms) was given as an iv bolus injection, in the morning after an overnight fast. Blood specimens were taken before and after injection at intervals up to 120 min, and plasma GH, adrenocorticotropin (ACTH), thyrotropin, prolactin, luteinizing hormone, follicle-stimulating hormone and cortisol were assayed by radioimmunoassays. A non-specific rise in plasma GH was demonstrated following injection of TRH and LH-RH, in 5 of 6 and 2 of 5 patients, respectively. In all subjects, rapid rises were observed in both plasma ACTH (34.3 +/- 6.2 pg/ml at 0 min to 79.5 +/- 9.5 pg/ml at 30 min, mean +/- SEM) and cortisol level (9.1 +/- 1.3 micrograms/dl at 0 min to 23.4 +/- 1.2 micrograms/dl at 90 min). However, plasma levels of GH and the other anterior pituitary hormones did not change significantly after CRF injection. These results indicate that CRF specifically stimulates ACTH secretion and any non-specific response of GH to CRF appears to be an infrequent phenomenon in this disorder.