Acromegaly due to ectopic growth hormone (GH)-releasing hormone (GHRH) production: dynamic studies of GH and ectopic GHRH secretion

Dynamic studies of GH and GH-releasing hormone (GHRH) secretion were performed in a man with a GHRH-producing carcinoid tumor and acromegaly. Insulin hypoglycemia stimulated and metoclopramide inhibited both GH and GHRH acutely. Bromocriptine suppressed GH both acutely and chronically without altering circulating GHRH levels and also blunted the GH response to exogenous GHRH. TRH acutely stimulated GH, but not GHRH, secretion, and iv bolus doses of synthetic GHRH-(1-40) stimulated GH release acutely. Somatostatin infusion decreased both GH and GHRH concentrations and blunted the GH responses to TRH and GHRH-(1-40). We conclude that prolonged exposure of the pituitary gland to high concentrations of GHRH is associated with chronic GH hypersecretion and may be accompanied by a preserved acute GH response to exogenous GHRH; a paradoxical response of GH to TRH may be mediated at the pituitary level, consequent to prolonged pituitary exposure to GHRH; bromocriptine suppression of GH in acromegaly is due to a direct pituitary effect of the drug; and somatostatin inhibits both ectopic GHRH secretion as well as GH responsiveness to GHRH in vivo. Since GH secretory responses in patients with somatotroph adenomas are similar to those in this patient, augmented GHRH secretion may play a role in development of the "classic" form of acromegaly.     

Acromegaly

In the majority of cases, acromegaly is due to GH hypersecretion by a somatotroph pituitary tumor. The etiology of acromegaly is not known, and may be related to GHRH hypersecretion, intrinsic pituitary defect, or a combination thereof. Recent physiologic data and molecular biology techniques provide insights into the pathophysiology of this condition. Treatment options include surgery, radiation, and judicious administration of pharmacologic compounds inhibiting GH secretion and tumor growth.     

Atypical McCune-Albright syndrome associated with growth hormone-prolactin pituitary adenoma: natural history, long-term follow-up, and SMS 201-995--bromocriptine combined treatment results.

A 35-yr-old woman is described as having atypical McCune-Albright syndrome, associated with acromegaly and hyperprolactinemia due to pituitary adenoma. The patient did not present sexual precocity, but primary amenorrhea. After transphenoidal adenomectomy, the GH plasma levels returned to normal, whereas the PRL values decreased; bromocriptine therapy normalized PRL levels and induced ovulatory menses. After 4 uneventful yr the patient developed relapse of active acromegaly that did not recover after a second neurosurgical exploration. Bromocriptine treatment maintained normal PRL levels but did not significantly reduce GH ones; the association with long-acting somatostatin analog SMS 201-995 by continuous sc pump infusion induced definitive control of GH and somatomedin-C secretion. These results suggest an additive inhibitory effect on GH secretion exerted by the two drugs.     

Neuroendocrine tumors secreting growth hormone-releasing hormone: Pathophysiological and clinical aspects

Hypothalamic GHRH is secreted into the portal system, binds to specific surface receptors of the somatotroph cell and elicits intracellular signals that modulate pituitary GH synthesis and/or secretion. Moreover, GHRH is synthesized and expressed in multiple extrapituitary tissues. Excessive peripheral production of GHRH by a tumor source would therefore be expected to cause somatotroph cell hyperstimulation, increased GH secretion and eventually pituitary acromegaly. Immunoreactive GHRH is present in several tumors, including carcinoid tumors, pancreatic cell tumors, small cell lung cancers, endometrial tumors, adrenal adenomas, and pheochromocytomas which have been reported to secrete GHRH. Acromegaly in these patients, however, is uncommon. The distinction of pituitary vs. extrapituitary acromegaly is extremely important in planning effective management. Regardless of the cause, GH and IGF-1 are invariably elevated and GH levels fail to suppress (<1 μg/l) after an oral glucose load in all forms of acromegaly. Dynamic pituitary tests are not helpful in distinguishing acromegalic patients with pituitary tumors from those harbouring extrapituitary tumors. Plasma GHRH levels are usually elevated in patients with peripheral GHRH-secreting tumors, and are normal or low in patients with pituitary acromegaly. Unique and unexpected clinical features in an acromegalic patient, including respiratory wheezing or dyspnea, facial flushing, peptic ulcers, or renal stones sometimes are helpful in alerting the physician to diagnosing non pituitary endocrine tumors. If no facility to measure plasma GHRH is available, and in the absence of MRI evidence of pituitary adenoma, a CT scan of the thorax and abdominal ultrasound could be performed to exclude with good approximation the possibility of an ectopic GHRH syndrome. Surgical resection of the tumor secreting ectopic GHRH should be the logical approach to a patient with ectopic GHRH syndrome. Standard chemotherapy directed at GHRH-producing carcinoid tumors is generally unsuccessful in controlling the activated GH axis. Somatostatin analogs provide an effective option for medical management of carcinoid patients, especially those with recurrent disease. In fact, long-acting somatostatin analogs may be able to control not only the ectopic hormonal secretion syndrome, but also, in some instances, tumor growth. Therefore, although cytotoxic chemotherapy, pituitary surgery, or irradiation still remain available therapeutic options, long-acting somatostatin analogs are now preferred as a second-line therapy in patients with carcinoid tumors and ectopic GHRH-syndrome.     

A case of fibrous dysplasia (McCune Albright syndrome) associated with acromegaly

We report a case of a 47-year-old woman with McCune-Albright syndrome associated with unusual growth-hormone and prolactin hypersecretion. Acromegaly was suspected on clinical examination, and she was referred to us. She had no history of precocious puberty or pathological fracture. She was 154cm tall, weighing 62kg with so-called acromegalic facies. There were two lumps, one of which was on her right lateral forehead. The other on the right lower extremity seemed to be due to a bone deformity. Some brown pigmented macules with irregular borders were present on her lips and oral mucosa. Endocrine examination revealed elevated basal levels of plasma GH (54ng/ml) and PRL (36.2ng/ml), which paradoxically increased after injection of TRH. Plasma levels of these hormones did not change after LHRH test, and plasma GH level increased after GHRH test. A skull X-ray film showed a double floor of the sella turcia and hyperostotic formation of the right sphenoid bone. MRI and CT showed a tumor shadow in the right sella turcica. Bone roentogenography of the right fibula and tibia showed a large centrally expanding lesion with a ground-glass or cystic appearance and a thin cortex. The left fibula showed a similar lesion. We recognized similar findings in other bones which also showed abnormal accumulation in a radionuclide bone scan with 99mTc. On the basis of physical, endocrinological and roentogenographical examination, we diagnosed her as displaying McCune-Albright syndrome. We operated on her by transsphenoidal surgery and confirmed a functioning chromophobe adenoma which was removed during surgery. She has been free of GH and PRL hypersecretion since then. The pathology of the sphenoidal sinus affected with fibrous bone was in accordance with the findings of fibrous dysplasia. McCune-Albright syndrome (MCAS) is known as a syndrome characterized by polyostotic fibrous dysplasia and cutaneous pigmentation and multiple endocrinopathy. Its etiology is unknown. This syndrome with acromegaly is rare, and although 26 cases have been described in literature, pathological examinations have been undertaken in only three cases. This case was very rare and valuable because, by operating on her by the transsphenoidal route in spite of the sphenoidal sinus being affected with fibrous bone, we were able to confirm a chromophobe adenoma secreting both GH and PRL. We recognized that acromegaly with MCAS was endocrinologically, morphologically and immunohistologically the same as acromegaly without MCAS. Therefore, we concluded that acromegaly with MCAS is much the same as acromegaly without MCAS.     

Acromegaly due to ectopic secretion of GHRH by bronchial carcinoid in a patient with empty sella

GH hyperproduction due to ectopic secretion of GHRH is a rare cause of acromegaly. Since 1959, approximately 50 cases of ectopic GHRH production from extrapituitary tumors have been described. Here we report the clinical and biochemical features of a 47-yr-old Caucasian woman with ectopic GHRH syndrome sustained by a bronchial carcinoid. The criteria for the diagnosis of acromegaly due to ectopic GHRH secretion were satisfied in our patient (i.e. confirmation of active GH hypersecretion, unequivocal demonstration of GHRH production and secretion from an extrapituitary tumor and cure of acromegaly after neoplasm removal). The tumor was an atypical carcinoid and there was a familial history of lung and colorectal cancer. Acromegaly was slightly active (mean GH value: 7.4 ng/ml, IGF-I: 436 ng/ml) and after tumor removal there was a progressive decline of GH levels, consistent with remission of pituitary somatotroph hyperplasia. Pituitary radiology showed an empty sella demonstrating for the first time its association with ectopic GHRH syndrome.     

Medical management of acromegaly due to ectopic production of growth hormone-releasing hormone by a carcinoid tumor

A 59-yr-old woman with a disseminated carcinoid tumor was evaluated for acromegaly. She had previously undergone a hypophysectomy for acromegaly and an enlarged pituitary, with a reduction in her serum GH levels from 100 to 4 micrograms/L. Recurrence of acromegalic symptoms 2 yr later was accompanied by elevated serum GH (16 micrograms/L) and insulin-like growth factor I (IGF-I; 528 micrograms/L) and plasma GHRH levels (12 micrograms/L; normal, less than 30 ng/L). Computed tomographic scan did not reveal pituitary enlargement. Metastatic carcinoid tissue in bone removed at biopsy contained GHRH (100 pg/mg tissue). High performance liquid chromatography of plasma GHRH revealed predominantly GHRH-(3-40)-OH, a biologically inactive GHRH metabolite, along with mature GHRH forms, while carcinoid tissue contained both GHRH-(1-40)-OH and GHRH-(1-44)-NH2. Treatment with pergolide initially resulted in reduction in serum GH and IGF-I levels and amelioration of symptoms of acromegaly. However, after 14 months of pergolide therapy, serum GH levels increased despite administration of up to 1000 micrograms pergolide/day. Plasma GHRH levels remained elevated throughout the treatment period. Subsequent treatment with SMS 201-995, a long-acting somatostatin analog, for over 1 yr resulted in sustained reductions of ectopic GHRH secretion, GH hypersecretion, and IGF-I levels. Plasma GHRH levels correlated with simultaneously measured serum GH levels in response to acute SMS 201-995 administration. SMS 201-995 was an effective medical treatment for acromegaly caused by ectopic GHRH production in this patient.     

McCune-Albright syndrome: growth hormone dynamics in pregnancy

Excess GH secretion has a well recognized association with McCune-Albright syndrome. Although there have been a number of reported pregnancies in uncontrolled acromegaly, none has been described in the McCune-Albright syndrome. We have studied the GH and insulin-like growth factor I (IGF-I) profiles in a patient with confirmed McCune-Albright syndrome and GH hypersecretion throughout a successful pregnancy and postpartum period. Prepregnancy, IGF-I was 60.6 nmol/L (normal, 18.0--43.1), and the daytime GH profile measured using assay A was 9.6--14.0 mU/L. At 13 weeks gestation there was a decline of IGF-I to 33.9 nmol/L and in the daytime GH profile (assay A) to 5.4--6.8 mU/L. At 24 weeks, IGF-I had risen to 51.6 nmol/L. A simultaneous daytime GH profile at this time using assay A revealed levels between 21.3--22.1 mU/L, but only 2.1--3.0 mU/L with assay B. Assay A has significant cross-reactivity with human placental lactogen (HPL), unlike assay B. At 36 weeks, IGF-I was still elevated at 56.6 nmol/L, with a daytime GH profile of 16.6--17.7 mU/L using assay A and 1.5--3.9 mU/L with assay B. At 12 weeks postpartum, IGF-I was 71.4 nmol/L, and the daytime GH profile with assay B was 5.6--8.6 mU/L. These data support a picture of GH suppression during pregnancy in acromegaly associated with McCune-Albright syndrome, shown best with assay B, which discriminates between GH and HPL. These results contrast with previous reports of pregnancy in uncontrolled acromegalics, in whom pituitary GH levels were unaffected by pregnancy, and total GH and IGF-I levels were noted to be elevated. These data suggest that GH secretion in a pregnant acromegalic with the McCune-Albright syndrome may not be entirely autonomous, as seen in classic acromegaly, but may be associated with a degree of negative feedback control that could be exerted by a circulating factor of placental origin, probably HPL or placental GH.     

Secretion of growth hormone-releasing hormone in patients with idiopathic pituitary dwarfism and acromegaly

The plasma levels of immunoreactive-GHRH in patients with idiopathic pituitary dwarfism and acromegaly were studied in the basal state and during various tests by a sensitive and specific RIA. The fasting plasma GHRH level in 22 patients with idiopathic pituitary dwarfism was 6.3 +/- 2.3 ng/l (mean +/- SD), which was significantly lower than that in normal children (9.8 +/- 2.8 ng/l, N = 21), and eight of them had undetectable concentrations (less than 4.0 ng/l). Little or no response of plasma GHRH to oral administration of L-dopa was observed in 7 of 10 pituitary dwarfs, and 3 of the 7 patients showed a response of plasma GH to iv administration of GHRH (1 microgram/kg). These findings suggest that one of the causes of idiopathic pituitary dwarfism is insufficient GHRH release from the hypothalamus. The fasting plasma GHRH level in 14 patients with acromegaly and one patient with gigantism was 8.0 +/- 3.9 ng/l, which was slightly lower than that in normal adults (10.4 +/- 4.1 ng/l, N = 72). One acromegalic patient with multiple endocrine neoplasia type I had a high level of plasma GHRH (270 ng/l) with no change in response to L-dopa and TRH test. In 3 untreated patients with acromegaly L-dopa did not induce any response of plasma GHRH in spite of inconsistent GH release, and in 4 patients with acromegaly, TRH evoked no response of plasma GHRH in spite of a marked GH release, suggesting that the GH responses are not mediated by hypothalamic GHRH.(ABSTRACT TRUNCATED AT 250 WORDS)     

Regulation of pulsatile growth hormone secretion by fasting in normal subjects and patients with acromegaly.

In acromegaly, GH hypersecretion occurs despite elevated insulin-like growth factor-I (IGF-I) levels, implying defective IGF-I feedback. To study the possible mechanisms of defective IGF-I negative feedback in acromegaly, we assessed parameters of pulsatile GH secretion during fasting-induced decrease in plasma IGF-I. Seven patients with active acromegaly and six normal controls were fasted for 6 days and GH secretory profiles were obtained by frequent (every 10 min) blood sampling for 24 h and analyzed by Cluster. Fasting resulted in similar decreases in IGF-I, body weight, and blood glucose levels, and increases in free fatty acid and beta-hydroxybutyrate in all subjects. Normal subjects showed increases in 24-h total and pulsatile GH production, GH pulse frequency, maximal pulse amplitude, interpulse and nadir levels, implying suppression of hypothalamic somatostatin secretion and increase in GH-releasing hormone (GHRH) pulse frequency. In acromegalic patients, GH (and, by inference, GHRH) pulse frequency was unchanged. Three patients had increases in GH production, interpulse, and nadir levels similar to the normals while the other four had no change or paradoxical decreases in these parameters. Percentage change in GH production was highly correlated with percentage change in interpulse and nadir levels in both normals and patients. Mean GH response to GHRH (0.33 micrograms/kg iv) did not change significantly in any group as a result of fasting. Our data suggest that in healthy humans IGF-I negative feedback on GH secretion involves suppression of GHRH pulse frequency. GH (and, by inference, GHRH) pulse frequency is resistant to decrease in IGF-I in acromegaly, suggesting that lowered sensitivity of GHRH neurons to IGF-I may be the mechanism of high GH pulse frequency in this disease.     

Octreotide suppresses both growth hormone (GH) and GH-releasing hormone (GHRH) in acromegaly due to ectopic GHRH secretion

Two patients with acromegaly secondary to ectopic GHRH secretion by metastatic carcinoid tumors were studied before and during therapy with the somatostatin analog octreotide (SMS 201-995). GH and GHRH secretory patterns were assessed during intermittent sc administration, continuous sc infusion (CSI), and continuous iv infusion of octreotide. Octreotide reduced serum GH and plasma GHRH levels in the two patients, although there was differential sensitivity of GH and GHRH. Intermittent sc therapy transiently lowered serum GH in both patients. A higher iv dose was required to reduce plasma GHRH by 50% than to reduce serum GH by 50% (2.0 vs. 0.05 micrograms/kg.h, respectively; patient 1). A similar pattern was found during CSI octreotide administration in the same patient. Chronic therapy with intermittent sc and CSI octreotide was assessed by serial 24-h profiles of GH and GHRH secretion in patient 2. Mean hourly serum GH levels decreased from a pretreatment level of 31.5 +/- 3.5 (+/- SE) to 9.5 +/- 1.5 micrograms/L during CSI therapy (1000 micrograms/day or 0.40 micrograms/kg.h). In contrast, plasma GHRH levels were less effectively suppressed. The mean serum GH levels and the variation in hourly GH values were reduced to a greater extent with CSI than with intermittent sc therapy. Serum insulin-like growth factor I also declined from 5.9 x 10(3) to 2.5 x 10(3) U/L during chronic CSI therapy (patient 2). CSI therapy with octreotide can be more effective than intermittent sc therapy in controlling GH excess in the rare syndrome of ectopic GHRH secretion, although serum GH may not decline to normal.     

Acromegaly due to ectopic growth hormone-releasing hormone secretion by a bronchial carcinoid tumour. Dynamic hormonal responses to various stimuli.

Ectopic GHRH is a relatively uncommon cause of acromegaly, which should be differentiated from pituitary adenoma, in order to avoid damage to the pituitary gland from unnecessary interventions. We report here on a 66-year-old man with acromegaly due to a GHRH-secreting bronchial carcinoid tumour, who recovered completely following removal of the tumour. His hormonal status was studied before and after the operation. Basal GH, GHRH, IGF-I and PRL levels, as well as plasma GH response to glucose load and TRH administration were abnormal before the operation, and became normal thereafter. The somatostatin analogue SMS 201-995 was found to be a potent inhibitor of the ectopic GHRH and the GH secretion (greater than 500 to 42 ng/l and 15.4 micrograms/l to 0.8 microgram/l, respectively). The effect on GHRH proved to be due to direct effect of somatostatin on the tumour cells, as demonstrated in tissue culture studies. A mixed meal was found immediately to suppress GHRH levels without such an effect on GH secretion. We conclude that the neuroendocrine tests usually practised in acromegaly cannot differentiate between ectopic GHRH secretion and pituitary adenoma. High plasma GHRH levels may serve as a diagnostic test for excessive GHRH production, which is almost always ectopic. These high levels are suppressible by somatostatin and a mixed meal.     

Secretion of alpha and TSH-beta subunits in patients with acromegaly: an in vivo study.

Plasma alpha and TSH-beta subunit responses to iv administration of GHRH were examined in 19 patients with active acromegaly. In 4 patients (21%), plasma alpha subunit levels were increased over 50% of basal levels after administration of GHRH, whereas plasma TSH-beta subunit levels were increased in response to GHRH in another 5 patients (26%). No patient showed simultaneous increases of alpha and beta subunits. After successful surgery, alpha and TSH-beta subunits did not respond to GHRH. These findings support the idea that some pituitary adenomas in acromegaly cosecrete GH and either alpha subunit or TSH-beta subunit.     

Thyrotropin-releasing hormone increases serum levels of growth hormone-releasing hormone and growth hormone in patients with acromegaly.

The effect of intravenous injection of thyrotropin-releasing hormone (TRH) on the plasma concentrations of growth hormone (GH) and growth hormone-releasing hormone (GHRH) was studied in seven patients with acromegaly and in five control subjects. TRH had no effect on plasma GH or GHRH in the five control subjects. A 'paradoxical' increase in plasma GH in response to TRH was observed in four of the seven patients with acromegaly. In these four patients plasma GHRH also increased in response to TRH. No TRH-induced increase in GHRH levels was observed in the other three patients with acromegaly who did not display an increase in GH in response to TRH. The present results imply that GHRH may be involved in the plasma GH response to TRH in patients with acromegaly.     

Pituitary-hormone secretion by thyrotropinomas

Hormone secretion by somatotropinomas, corticotropinomas and prolactinomas exhibits increased pulse frequency, basal and pulsatile secretion, accompanied by greater disorderliness. Increased concentrations of growth hormone (GH) or prolactin (PRL) are observed in about 30% of thyrotropinomas leading to acromegaly or disturbed sexual functions beyond thyrotropin (TSH)-induced hyperthyroidism. Regulation of non-TSH pituitary hormones in this context is not well understood. We there therefore evaluated TSH, GH and PRL secretion in 6 patients with up-to-date analytical and mathematical tools by 24-h blood sampling at 10-min intervals in a clinical research laboratory. The profiles were analyzed with a new deconvolution method, approximate entropy, cross-approximate entropy, cross-correlation and cosinor regression. TSH burst frequency and basal and pulsatile secretion were increased in patients compared with controls. TSH secretion patterns in patients were more irregular, but the diurnal rhythm was preserved at a higher mean with a 2.5 h phase delay. Although only one patient had clinical acromegaly, GH secretion and IGF-I levels were increased in two other patients and all three had a significant cross-correlation between the GH and TSH. PRL secretion was increased in one patient, but all patients had a significant cross-correlation with TSH and showed decreased PRL regularity. Cross-ApEn synchrony between TSH and GH did not differ between patients and controls, but TSH and PRL synchrony was reduced in patients. We conclude that TSH secretion by thyrotropinomas shares many characteristics of other pituitary hormone-secreting adenomas. In addition, abnormalities in GH and PRL secretion exist ranging from decreased (joint) regularity to overt hypersecretion, although not always clinically obvious, suggesting tumoral transformation of thyrotrope lineage cells.     

Rab18 is reduced in pituitary tumors causing acromegaly and its overexpression reverts growth hormone hypersecretion

CONTEXT: Rab proteins regulate the sequential steps of intracellular membrane transport. Alterations of these GTPases and their associated proteins are emerging as the underlying cause for several human diseases involving dysregulated secretory activities. OBJECTIVE: Herein we investigated the role of Rab18, which negatively regulates hormone secretion by interacting with secretory granules, in relation to the altered functioning of tumoral pituitary somatotropes causing acromegaly. PATIENTS: A total of 18 patients diagnosed with pituitary tumors causing acromegaly (nine patients) or nonfunctioning adenomas (nine patients) underwent endoscopic transsphenoidal surgery. Adenomas were subsequently processed to evaluate Rab18 production in relation to GH secretion. RESULTS: We found that somatotropinoma cells are characterized by a high secretory activity concomitantly with a remarkably reduced Rab18 expression (15%) and protein content levels (30%), as compared with cells from nonfunctioning pituitary adenomas derived from patients with normal or reduced GH plasma levels (100%). Furthermore, immunoelectron microscopy revealed that Rab18 association with the surface of GH-containing secretory granules was significantly lower in somatotropes from acromegalies than nonfunctioning pituitary adenomas. Finally, we provide evidence that modulation of Rab18 gene expression can revert substantially the hypersecretory activity of cells because Rab18 overexpression reduced by 40% the capacity of cells from acromegalies to respond to GHRH stimulation. CONCLUSION: These results suggest that molecular alterations affecting individual components of the secretory granule traffic machinery can contribute to maintain a high level of GH in plasma. Accordingly, Rab18 constitutes a valuable target as a diagnostic, prognostic, and/or therapeutic tool for human acromegaly.     

Acromegaly, multinodular goiter and silent polyostotic fibrous dysplasia. A variant of the McCune-Albright syndrome

A 36-year-old woman is reported with a possible variant of the McCune-Albright syndrome. The triad was incomplete because of the absence of skin pigmentation and since the sexual precocity was not evident. The presence of a pituitary mass and the secretory dynamics of growth hormone and prolactin were suggestive of a mammosomatotroph cell adenoma. A toxic multinodular goiter was also associated, but unique was the spontaneous normalization of the thyroid function. Unusual was the silent evolution of the polyostotic fibrous dysplasia, which was only fortuitously discovered during magnetic resonance imaging of the pituitary region. Treatment of the acromegaly with the long-acting somatostatin analogue octreotide resulted in an important inhibition of the GH secretion and in a reduction of the volume of the pituitary adenoma.     

GH deficiency in patients irradiated for acromegaly: significance of GH stimulatory tests in relation to the 24 h GH secretion

BACKGROUND: Radiotherapy for pituitary adenomas frequently leads to GH deficiency (GHD). The characteristics of GH secretion in GHD induced by postoperative radiotherapy for acromegaly are not known. HYPOTHESIS: In the long term, stimulated and spontaneous GH release is not different between patients with GHD treated by postoperative radiotherapy for acromegaly or for other pituitary adenomas. DESIGN/SUBJECTS: We compared the characteristics of basal and stimulated GH secretion in patients with GHD, who had previously received adjunct radiotherapy after surgery for GH-producing adenomas (n=10) vs for other pituitary adenomas (n=10). All patients had a maximal GH concentration by insulin tolerance test (ITT) of 3 microg/l or less, compatible with severe GHD. Mean time after radiation was 17 and 18.7 years, respectively. Stimulated GH release was also evaluated by infusion of growth hormone-releasing hormone (GHRH), GHRH-arginine and arginine, and spontaneous GH by 10 min blood sampling for 24 h. Pulse analyses were performed by Cluster and approximate entropy. OUTCOMES: There were no differences between both patient groups in stimulated GH concentrations in any test. Spontaneous GH secretion was not different between both patient groups, including basal GH release, pulsatility and regularity. Pulsatile secretion was lost in two acromegalic and three non-acromegalic patients. Insulin-like growth factor-I (IGF-I) was below -2 s.d. score in nine patients in each group. CONCLUSION: Acromegalic patients treated by surgery and postoperative radiotherapy with an impaired response to the ITT do not differ, in the long term, in GH secretory characteristics from patients treated similarly for other pituitary tumors with an impaired response to the ITT. The ITT (or the GHRH-arginine test) is therefore reliable in establishing the diagnosis of GHD in patients treated for acromegaly by surgery and radiotherapy.     

Acromegaly with negative pituitary MRI and no evidence of ectopic source: the role of transphenoidal pituitary exploration?

Growth hormone (GH) producing adenomas of the pituitary gland are usually macroadenomas (>10 mm in size). Often these adenomas are locally invasive by the time of diagnosis. Acromegaly secondary to a very small pituitary microadenoma not visualized on pituitary magnetic resonance (MR) imaging is rare. We report a patient with acromegaly and an unremarkable pituitary MR imaging who had negative work up for ectopic growth hormone-releasing hormone (GHRH) or GH secreting tumors. Transsphenoidal pituitary exploration revealed a pituitary adenoma located on the left side of the sella against the medial wall of the cavernous sinus extending posteriorly along the floor of the sella all the way to the right side. The acromegaly was treated with resection of the pituitary adenoma and normalization of serum insulin-like growth factor 1 (IGF-1) and GH levels. In a patient with acromegaly and unremarkable pituitary MR imaging, with no evidence of ectopic GH and GHRH production, transsphenoidal pituitary exploration is a reasonable approach and may result in clinical improvement and biochemical cure in the hand of experienced surgeon. This approach may avoid long term medical treatment with its associated cost.     

Regulation of human growth hormone secretion and its disorders

Growth hormone (GH) secretion from anterior pituitary is regulated by the hypothalamus and the mediators of GH actions. Major regulatory factors include GH releasing hormone (GHRH), somatostatin (SRIF), GH releasing peptide (ghrerin) and insulin-like growth factor (IGF-I). The principal physiological regulation mechanisms of GH secretion are neural endogenous rhythm, sleep, stress, exercise, and nutritional and metabolic signals. GH deficiency results from various hereditary or acquired causes, which may be isolated or combined with other pituitary hormone deficiencies. GH deficiency can be treated with recombinant human GH, which results in accelerating growth in children and normalization of intermediary metabolism in adults. GH hypersecretion mostly results from a pituitary tumor and causes acromegaly or gigantism. Hypersecretion of GH can be treated by transshenoidal surgery. Medical treatment with octreotide and analogs is also effective to reduce GH secretion in combination with or without the surgery.