[Substitution with thyroid hormones in the elderly : Goals and risks]. / Substitution mit Schilddrüsenhormonen im höheren Lebensalter : Ziele und Gefahren.

Substitution with thyroid hormones is indicated in elderly patients with overt hypothyroidism, especially, when they present with typical symptoms of hypothyroidism. In light of the current study situation, the use of levothyroxine to treat clinical hypothyroidism in elderly patients is still controversial. In a recent double-blind, randomized, placebo-controlled study, levothyroxine provided no apparent benefits in older persons with subclinical hypothyroidism. The impact of levothyroxine therapy in patients with subclinical hypothyroidism on cardiovascular risk is not completely clear. Levothyroxine treatment is safe and free of side effects, when the thyroid-stimulating hormone (TSH) levels remain within the normal range. Prescription of levothyroxine in patients with only slightly elevated TSH levels often leads to overtreatment, which is associated with an increased risk of fractures, neurological and psychological symptoms, and atrial fibrillation. The recommendations of the European Thyroid Association is to treat elderly patients only when the TSH value is greater than 10 mU/l and the patient is symptomatic or the patient has a high cardiovascular risk. The therapeutic TSH range in elderly patients in the case of levothyroxine treatment should be 1.0-5.0 mU/l. Follow-up of the TSH level is mandatory in order to not oversee a developing overt hypothyroidism and to avoid overtreatment in case of levothyroxine treatment.

Somatostatin receptors in human endocrine tumors.

A selection of 90 mainly endocrine but nonpituitary tumors have been tested for their content of specific somatostatin receptors using receptor autoradiography. Somatostatin receptors were detected in the following tumors: in all 5 meningiomas tested; in 3 of 39 malignant breast tumors; and in 3 growth hormone releasing factor-producing tumors, i.e., one mediastinal carcinoid, one intestinal carcinoma, and its liver metastasis. Receptor density varied greatly among individual tumors. Some of the positive tumors were biochemically characterized using in vitro binding assay and were shown to have saturable and high affinity receptors with pharmacological specificity for somatostatin. The following tumors did not contain somatostatin receptors: prostate carcinomas (n = 17); prostate hyperplasia (n = 2); ovarian carcinomas (n = 6); endometrial carcinomas (n = 4); primary liver cell carcinomas (n = 3); pheochromocytomas (n = 3); aldosteronomas (n = 2); medullary thyroid carcinomas (n = 2); one adrenocorticotropic hormone-secreting pulmonary carcinoid; one astrocytoma; one neurofibroma; one lung tumor; and one bladder tumor. Somatostatin receptors can be found in benign or malignant tumors, originating in part from tissue not primarily known as a somatostatin target. The biological function of such receptors is, therefore, partly unknown. If they can mediate antiproliferative properties, as has been suggested to be the case for somatostatin receptors in selected endocrine tumors in rats and humans, the present data could be of potential therapeutic interest.

Ketoconazole inhibits corticotropic cell function in vitro.

The effects of ketoconazole (KC) on secretion and biosynthesis of ACTH and generation of cAMP in rat anterior pituitary cells were investigated in vitro. KC inhibits CRF-stimulated ACTH release from rat anterior pituitary fragments in a dose-dependent fashion between 1.5 and 100 microM. The effect of CRF as a releaser of ACTH was fully restored after KC was removed from the medium. Similar effects were observed in primary cultures of rat anterior pituitary cells. KC dose-dependently decreased basal and CRF-stimulated ACTH release. In addition, basal and CRF-stimulated mRNA coding for the ACTH precursor were reduced after preincubation with KC. The effects of KC on ACTH release and biosynthesis seem to be mediated by cAMP, since KC inhibits basal and CRF-stimulated cAMP release and content within the same dose range. Since the stimulatory effects of cholera toxin, sodium fluoride, and forskolin were dose-dependently inhibited by KC and since the addition of (Bu)2cAMP abolished the inhibiting effect of KC, it is concluded that KC acts by inhibition of the catalytic component of the adenylate cyclase holoenzyme.

Nitroimidazole derivatives inhibit anterior pituitary cell function apparently by a direct effect on the catalytic subunit of the adenylate cyclase holoenzyme.

Nitroimidazole derivatives dose-dependently decreased basal and CRF-stimulated ACTH release, basal and GRF-stimulated rat GH release, and basal rat PRL release in primary cultures of rat anterior pituitary cells. In addition, basal and CRF-stimulated mRNA coding for the ACTH precursor were reduced after preincubation with the nitroimidazole derivatives. Miconazole, econazole, isoconazole, clotrimazole, and bifonazole had similar or more pronounced effects on anterior pituitary function compared to ketoconazole, whereas metronidazole and etomidate were less effective. The positive correlation between the number of phenylated side-chains or phenolic rings of the imidazole molecule and the efficacy to inhibit activity on pituitary hormone secretion suggests a structure-activity relationship of these compounds. The effects of the nitroimidazole derivatives on anterior pituitary hormone release and biosynthesis were mediated by cAMP. Thus, basal and CRF-, cholera toxin-, and forskolin-stimulated adenylate cyclase activities in rat anterior pituitary cell membranes determined by cAMP formation were suppressed by the nitroimidazole derivatives. Pertussis toxin did not diminish the nitroimidazole derivative effect on cAMP formation. The adenylate cyclase inhibitory effect of these substances was independent of the presence of GTP in the assay system, underlining a direct effect on the catalytic subunit. In addition, basal and forskolin-stimulated cAMP generation in membranes of S49 lymphoma cyc-variants, which lack a functional Gs protein, was efficiently suppressed (by up to 90%) by the nitroimidazole derivatives. In conclusion, ketoconazole and other nitroimidazole derivatives inhibit anterior pituitary hormone synthesis and secretion apparently by a direct effect on the catalytic subunit of the adenylate cyclase system.

Arginine stimulates growth hormone secretion by suppressing endogenous somatostatin secretion.

To determine how arginine (Arg) stimulates GH secretion, we investigated its interaction with GHRH in vivo and in vitro. Six normal men were studied on four occasions: 1) Arg-TRH, 30 g arginine were administered in 500 mL saline in 30 min, followed by an injection of 200 micrograms TRH; 2) GHRH-Arg-TRH, 100 micrograms GHRH-(1-44) were given iv as a bolus immediately before the Arg infusion, followed by 200 micrograms TRH, iv; 3) GHRH test, 100 micrograms GHRH were given as an iv bolus; and 4) TRH test, 200 micrograms TRH were given iv as a bolus dose. Blood samples were collected at 15-min intervals for 30 min before and 120 min after the start of each infusion. Anterior pituitary cells from rats were coincubated with Arg (3, 6, 15, 30, and 60 mg/mL) and GHRH (0.05, 1, 5, and 10 nmol/L) for a period of 3 h. Rat GH was measured in the medium. After Arg-TRH the mean serum GH concentration increased significantly from 0.6 to 23.3 +/- 7.3 (+/- SE) micrograms/L at 60 min. TRH increased serum TSH and PRL significantly (maximum TSH, 11.1 +/- 1.8 mU/L; maximum PRL, 74.6 +/- 8.4 micrograms/L). After GHRH-Arg-TRH, the maximal serum GH level was significantly higher (72.7 +/- 13.4 micrograms/L) than that after Arg-TRH alone, whereas serum TSH and PRL increased to comparable levels (TSH, 10.2 +/- 3.0 mU/L; PRL, 64.4 +/- 13.6 micrograms/L). GHRH alone increased serum GH to 44.9 +/- 9.8 micrograms/L, significantly less than when GHRH, Arg, and TRH were given. TRH alone increased serum TSH to 6.6 +/- 0.6 mU/L, significantly less than the TSH response to Arg-TRH. The PRL increase after TRH only also was lower (47.2 +/- 6.8 micrograms/L) than the PRL response after Arg-TRH. In vitro Arg had no effect on basal and GHRH-stimulated GH secretion. Our results indicate that Arg administered with GHRH led to higher serum GH levels than did a maximally stimulatory dose of GHRH or Arg alone. The serum TSH response to Arg-TRH also was greater than that to TRH alone. We conclude that the stimulatory effects of Arg are mediated by suppression of endogenous somatostatin secretion.

Corticotropin releasing factor: a new tool for the differential diagnosis of Cushing's syndrome.

One-hundred micrograms corticotropin-releasing factor (CRF) was administered as an i.v. bolus to 6 women and one man patient with pituitary ACTH dependent Cushing's disease, one patient with ectopic ACTH secretion from a lung oat cell carcinoma, and 2 patients with hypercortisolism due to an unilateral adrenal adenoma and adrenal carcinoma. Though 4 out of 7 patients with pituitary ACTH-dependent Cushing's disease had normal basal ACTH levels, all 7 patients showed hyperresponsiveness of ACTH secretion after CRF administration compared to normal controls. Cortisol levels showed a similar pattern, with a significantly higher cortisol increase compared to normal controls. In contrast ACTH hypersecretion of ectopic origin could not be stimulated further by CRF administration, ACTH and cortisol remaining unchanged over the test period of 120 minutes. Suppressed ACTH levels below 5 pg/ml in the 2 patients with hypercortisolism of adrenal origin remained suppressed and cortisol levels did not change after CRF. We conclude that CRF administration is an effective tool in the differential diagnosis of Cushing's syndrome.

Growth hormone (GH) and prolactin responses to repetitive administration of GH-releasing hormone in acromegaly.

We investigated the pattern of GH secretion in response to repetitive GH-releasing hormone (GHRH) administration in patients with active acromegaly and in normal subjects. Twelve acromegalic patients (nine women and 3 men; aged 21-76 yr) were studied. Eight had never been treated, whereas four had undergone neurosurgery but still had active disease. All patients and eight normal subjects received three doses of 50 micrograms GHRH, iv, at 2-h intervals. Seven patients were retested 6-8 weeks after transsphenoidal removal of a pituitary adenoma. There was a marked serum GH rise in acromegalic patients and normal subjects after the first GHRH dose [area under the curve, 2070 +/- 532 (+/- SE) vs. 1558 +/- 612 ng/min X ml, respectively; P = NS]. Successive GHRH doses stimulated GH release only in acromegalic patients (second dose, 1123 +/- 421 ng/min X ml; third dose, 2293 +/- 1049 ng/min X ml). In normal subjects, the GH response to the second and third GHRH doses was blunted (second dose, 86 +/- 32 ng/min X ml; third dose, 210 +/- 63 ng/min X ml; P less than 0.01). PRL secretion did not change in normal subjects, whereas 6 of 12 acromegalic patients had PRL release after each GHRH dose (PRL responders to GHRH). Transsphenoidal surgery led to normalization (less than 5 ng/ml) of the preoperatively elevated GH levels in all but 2 patients, who, however, had reduction of somatomedin-C levels. The amount of GH released in the postoperative test was significantly lower than that released preoperatively (first dose, 722 +/- 209 vs. 2945 +/- 743 ng/min X ml; second dose, 358 +/- 117 vs. 1737 +/- 633 ng/min X ml; third dose, 320 +/- 144 vs. 1776 +/- 676 ng/min X ml, respectively; P less than 0.05 in all instances). Thus, patients with active acromegaly, but not normal subjects, respond to repetitive GHRH administration at 2-h intervals with an increase in GH levels. This increase may be due to a larger releasable GH pool and/or faster GH turnover in the adenomatous cell.

Growth hormone-releasing hormone infusion in patients with active acromegaly.

To determine GH-releasing hormone (GHRH)-stimulated GH secretion in patients with active acromegaly, nine patients received a 50-microgram GHRH-(1-44) bolus dose followed by a 2-h infusion with 100 micrograms GHRH/h, after which a second 50-microgram GHRH bolus dose was given. Serum GH, PRL, and immunoreactive GHRH levels were measured from 2 h before to 1 h after the end of the infusion and compared with hormone levels in six normal subjects subjected to the same protocol. In addition, seven of the nine acromegalic patients received 100 micrograms GHRH as an iv bolus dose, followed by a 2-h saline infusion on a different day. After the 100-micrograms GHRH bolus dose, the mean GH level increased from 55.9 +/- 18.0 (+/- SE) to 148.5 +/- 40.0 ng/ml within 15 min. Thereafter, GH levels decreased and were significantly lower at 90 and 120 min compared to the peak level 15 min after GHRH injection. After the 50-micrograms GHRH bolus dose, all acromegalic patients except two also had a clear-cut rise of GH levels, with the mean GH level increasing from 37.5 +/- 13.2 to 108.4 +/- 55.0 ng/ml at 60 min. Thereafter, elevated GH levels were sustained in the acromegalic patients throughout the GHRH infusion. In contrast, normal subjects had a significant decrease in the initially elevated GH levels, despite continuous GHRH infusion. There were no significant differences between PRL secretion and immunoreactive GHRH levels in either group. These findings suggest that patients with active acromegaly not only have elevated basal GH levels, but also have a greater ready releasable GH pool and/or accelerated GH turnover compared to those of normal subjects, which cannot be exhausted by a 2-h GHRH infusion.

Criteria for cure of acromegaly: a consensus statement.

In February 1999, a workshop was held in Cortina, Italy to develop a consensus defining the criteria for cure of acromegaly. The workshop was sponsored by the University of Brescia and hosted by the Italian Society of Endocrinology. Invited international participants included endocrinologists, neurosurgeons, and radiotherapists skilled in the management of acromegaly. This statement summarizes the consensus achieved in these discussions.

Altered hypothalamic-pituitary-adrenal responsiveness to dexamethasone-insulin tolerance test in active acromegaly.

Eight acromegalic patients showed a plasma cortisol (11-OHCS) rise after insulin hypoglycemia which was similar to that seen in control patients, with mean peak values (+/-SEM) of 23.2 +/- 3.5 mug/100 ml and 27.2 +/- 3.3 mug/100 ml, respectively. One mg of dexamethasone was given the evening prior to repeat insulin hypoglycemia (DEX-ITT). After dexamethasone, the control subjects showed a mean post hypoglycemic plasma 11-OHCS rise to 18.3 +/- 2.3 mug/100 ml. In contrast, acromegalic patients had a negligible rise is plasma 11-OHCS, despite a comparable degree of hypoglycemia. These data indicate that, in active acromegaly, abnormal hypothalamic-pituitary-adrenal suppressibility can be induced to insulin hypoglycemia after dexamethasone.

Presence of growth hormone-releasing hormone-like immunoreactivity in human tumors: characterization of immunological and biological properties.

The distribution and physical and biological properties of GH-releasing hormone-like immunoreactivity (GHRH-IR) in human tissues and tumors was investigated using a specific GHRH RIA, gel chromatography, immunoaffinity chromatography, and bioassay with cultured rat anterior pituitary cells. Variable concentrations of GHRH-IR, ranging from 1.4-39.0 ng/g wet wt, were found in normal liver, lung, placenta, and pancreas. In the latter tissue, however, a different chromatographic profile and a marked decrease in GHRH-IR after immunoaffinity occurred, suggesting that GHRH-IR in pancreatic extracts is not native GHRH. In all tumors examined (n = 35) GHRH-IR could be detected, and four tumors (three carcinoids and one jejunal carcinoma) contained a very high amount of GHRH-IR (greater than 1000 ng/g wet wt). Affinity chromatography of tumor extracts led to a significant loss (greater than 50%) of GHRH-IR in nine tumors. The four tumors containing large amounts of GHRH-IR were obtained from two patients with active acromegaly and two patients who had no clinical evidence of acromegaly. Using antibodies with different specificities for GHRH-(1-44) and GHRH shortened at the C-terminus, varying concentrations of GHRH-(1-44) in these tumors were found, ranging from 10-87% of the total GHRH-IR. The biological activity of GHRH in the four tumor extracts was similar to that of synthetic GHRH alone or GHRH added to control tissue subjected to extraction. These results demonstrate the presence of GHRH-IR in the majority of normal tissues and tumors, which, though they may produce large amounts of biologically active GHRH, do not always lead to acromegaly.

Growth hormone (GH)-releasing peptide stimulation of GH release from human somatotroph adenoma cells: interaction with GH-releasing hormone, thyrotropin-releasing hormone, and octreotide.

The synthetic hexapeptide GH-releasing peptide (GHRP; His-D-Trp-Ala-Trp-D-Phe-Lys-NH2) specifically stimulates GH secretion in humans in vivo and in animals in vitro and in vivo via a still unknown receptor and mechanism. To determine the effect of GHRP on human somatotroph cells in vitro, we stimulated cell cultures derived from 12 different human somatotroph adenomas with GHRP alone and in combination with GH-releasing hormone (GHRH), TRH, and the somatostatin analog octreotide. GH secretion of all 12 adenoma cultures could be stimulated with GHRP, whereas GHRH was active only in 6 adenoma cultures. In GHRH-responsive cell cultures, simultaneous application of GHRH and GHRP had an additive effect on GH secretion. TRH stimulated GH release in 4 of 7 adenoma cultures; in TRH-responsive cell cultures there was also an additive effect of GHRP and TRH on GH secretion. In 5 of 9 adenoma cultures investigated, octreotide inhibited basal GH secretion. In these cell cultures, GHRP-induced GH release was suppressed by octreotide. In 5 of 5 cases, the protein kinase-C inhibitor phloretin partly inhibited GHRP-stimulated GH release, but not basal GH secretion. In summary, GH secretion was stimulated by GHRP in all somatotroph adenomas investigated, indicating that its unknown receptor and signaling pathway are expressed more consistently in somatotroph adenoma cells than those for GHRH, TRH, and somatostatin. Our data give further evidence that GHRP-stimulated GH secretion is mediated by a receptor different from that for GHRH or TRH, respectively, and that protein kinase-C is involved in the signal transduction pathway. Because human somatotroph adenoma cell cultures respond differently to various neuropeptides (GHRH, TRH, somatostatin, and others), they provide a model for further investigation of the mechanism of action of GHRP-induced GH secretion.

Effect of bromocriptine and SMS 201-995 on growth of human somatotrophic and non-functioning pituitary adenoma cells in vitro.

The effect of the dopamine agonist bromocriptine and the somatostatin analog SMS 201-995 on growth of 12 human somatotrophic and 13 non-functioning adenoma cell cultures was investigated. When adenoma cells were maintained in medium supplemented with 5% fetal calf serum, cell counts of 10 of 12 somatotrophic cultures increased to 145 +/- 6 and 171 +/- 9% (mean +/- SD) and in 12 of 13 non-functioning cell cultures up to 125 +/- 12 and 217 +/- 15% after 3 days of incubation. In most cases bromocriptine and SMS 201-995 dose dependently (1 nmol/l to 10 mumol/l) inhibited adenoma cell growth but there was only (1, 10 mumol/l) a significant inhibitory effect at high doses of both drugs. A 1 mumol/l concentration of bromocriptine decreased cell counts of 5 of 12 somatotrophic cell cultures (range 84 +/- 3 to 76 +/- 6% vs control = 100%) and in 5 of 13 non-functioning cell cultures (range 85 +/- 4 to 71 +/- 7%). A 10 mumol/l concentration of bromocriptine decreased cell counts in all 12 somatotrophic (range 87 +/- 1 to 61 +/- 8%) and in 12 of 13 non-functioning adenoma cultures (range 87 +/- 6 to 57 +/- 3%). Bromocriptine specifically inhibited growth because its effect could be reversed by the dopamine D2-receptor antagonist haloperidol. Both 1 and 10 mumol/l SMS 201-995 significantly decreased cell counts in three of six somatotrophic (87 +/- 3 to 38 +/- 3%) cell cultures. In two of five cases growth of non-functioning adenoma cultures was suppressed by 1 mumol/l SMS 201-995, and in four of five cases by 10 mumol/l (86 +/- 3 to 74 +/- 4%). The growth inhibitory effect of both bromocriptine and SMS 201-995 was not just due to an effect on growth of fibroblasts contaminating the adenoma cell cultures, because it could be observed also when adenoma cells were maintained in a D-valine-supplemented medium that suppresses fibroblast growth. In summary, both bromocriptine and SMS 201-995 at high doses were able to inhibit cell growth of cultured somatotrophic and non-functioning adenomas in vitro. However, the mechanism of this inhibitory effect is not yet well understood.

Corticotropin-releasing factor (CRF): stimulation in normal controls and in patients with Cushing's syndrome.

Synthetic ovine and human CRF were given as an i.v. bolus to six healthy volunteers in four and two different dosages, respectively (oCRF: 25, 50, 100 and 200 micrograms; hCRF: 50 and 100 micrograms). There was a significant increase of ACTH and cortisol after the injection of all dosages though the dose-response relationship was only significant between the 50 and 100 micrograms dose of oCRF. No significant differences between ACTH and cortisol secretion after oCRF and hCRF were observed. Repetitive stimulation by hCRF led to repetitive release of identical amounts of ACTH. The CRF test with the 100 micrograms dosage was used in patients with proven Cushing's syndrome (n = 30). Results showed that the CRF test is useful in making the differential diagnosis of established Cushing's syndrome. In patients with ACTH-dependent Cushing's disease (n = 21), normal or elevated basal ACTH levels were significantly higher after stimulation by CRF compared to normal controls, with one exception. The pattern of cortisol secretion after CRF administration corresponded to the pattern of ACTH secretion in these patients. In two patients with ectopic ACTH syndrome, extremely elevated ACTH and cortisol levels did not change or showed only a small increase after CRF administration. In patients with unilateral adrenal adenoma or carcinoma (n = 7), suppressed ACTH levels did not rise after CRF administration. In addition, no significant change in cortisol secretion could be observed. After surgical removal of cortisol-producing adrenal tumors, the ACTH response to CRF can be demonstrated when cortisol levels are still undetectable. Pulsatile administration of CRF in one patient after unilateral adrenalectomy revealed that ACTH responses to CRF normalize rapidly but cannot be sustained if CRF administration is withdrawn, suggesting that the cause of adrenal failure after unilateral adrenalectomy for Cushing's syndrome or with long-term corticoid therapy is due to hypothalamic CRF deficiency. The suppression of ACTH responses to CRF in glucocorticoid-treated patients correlated with the daily corticoid dosage. Since the ACTH hyper-response to CRF in six patients with Cushing's disease was suppressed by short-term dexamethasone treatment, the pituitary as a target site for feedback inhibition also was demonstrated.

Ectopic production of ACTH and corticotropin-releasing hormone (CRH).

The most common ectopic production of a pituitary hormone is the one of ACTH leading to Cushing's syndrome. Ectopic ACTH-hypersecretion is the cause of Cushing's syndrome in 10-15% of all cases. The ACTH-secreting tumours are often oat-cell carcinomas of the lung, less frequently pancreatic cancers, hypernephromas, or C-cell carcinomas of the thyroid. Some of these tumours may be benign or semi-benign as the rare carcinoid tumours and cause great problems in the differential diagnosis of ACTH-dependent hypercortisolism. Out of 173 of our patients with Cushing's syndrome observed in the last 12 years 21 were caused by ectopic ACTH-production. Of these 21 patients 13 have a small cell carcinoma of the lung. The ectopic ACTH-syndrome often has typical clinical features caused by the levels of ACTH and cortisol leading to hypocalcemic alkalosis with muscle weakness and wasting, carbohydrate intolerance, and hypertension with oedema. The survival time in many of these patients is not long enough to allow them to develop typical signs of Cushing's syndrome though they are often highly pigmented. These patients are easily diagnosed. However, patients with small tumours which do not cause very elevated ACTH-levels and who have the more typical clinical signs of full-blown Cushing's syndrome are difficult to recognize. For the differential diagnosis of ACTH-dependent Cushing's syndrome the corticotropin-releasing hormone (CRH) stimulation test and dexamethasone suppression test with high doses are helpful. In special cases the venous sampling procedure for ACTH-measurements is necessary, also CT or NMR is helpful. Ectopic CRH-production is a rare cause of ACTH-dependent Cushing's syndrome. Patients with ectopic CRH-production and consecutive ACTH-hypersecretion from the pituitary have not been studied extensively. There are especially no well documented results of the use of the CRH-stimulation test in vivo in this group of patients with Cushing's syndrome. On the other hand, in the documented cases, not only CRH-, but also ACTH-production was found in the tumours. So far, this rare cause of ACTH-dependent Cushing's syndrome has to be excluded or confirmed by the measurement of endogenous CRH-levels. But until now we have not been able to detect one single case of ectopic CRH-production using a sensitive homologous CRH-radioimmunoassay over a period of more than 8 years in which we have seen nearly 120 newly diagnosed patients with ACTH-dependent Cushing's syndrome. Only in the plasma and tumour tissue of two patients of other groups have we found high CRH-levels.

Potential indications for octreotide in endocrinology.

Treatment with Sandostatin is established in acromegaly, thyroid-stimulating hormone (TSH)-producing pituitary, and endocrine-active gastroenteropancreatic tumors. Potential indications include ectopic hormone syndromes, medullary thyroid carcinomas, pituitary resistance to thyroid hormones, tall stature children, diabetes mellitus and diabetic complications, polycystic ovary syndrome, and Graves' ophthalmopathy. Particularly in the ectopic growth hormone-releasing hormone (GHRH) syndrome, Sandostatin is unequivocally effective and, in the ectopic corticotropin syndrome selected cases can be treated successfully with Sandostatin, leading to marked clinical improvement. In many of the above situations, only subgroups show a response to Sandostatin, which may be identified by scintigraphy with labeled Sandostatin. This pertains also to Graves' ophthalmopathy, for which Sandostatin may be particularly promising and where positive and negative Sandostatin scans have been demonstrated. However, for all these potential indications, larger, well-studied series are needed, before definitive conclusions can be drawn.

Somatostatin analogs in ectopic corticotropin production.

Eutopic corticotroph pituitary adenomas and adrenal cortisol-producing adenomas do not usually express somatostatin receptors. However, ectopic corticotropin (ACTH)-producing tumors often express somatostatin receptors. Thus, the octreoscan can detect and localize tumors in 80% of patients with ectopic ACTH syndrome, and so it can be used to differentiate between eutopic and ectopic ACTH-dependent bilateral adrenal hyperplasia. Octreotide therapy can produce a rapid and sustained reduction of ACTH and cortisol levels in patients with ectopic ACTH-dependent Cushing's syndrome and, in some, may be the only long-term therapy possible. Although no large series have been reported, a review of the literature reveals a large number of case reports that have demonstrated the effectiveness of octreotide.

Comparison of gonadotropin-releasing hormone and gonadotropin therapy in male patients with idiopathic hypothalamic hypogonadism.

OBJECTIVE: To compare pulsatile gonadotropin-releasing hormone (GnRH) therapy with gonadotropin therapy in male patients with idiopathic hypothalamic hypogonadism. DESIGN: Prospective study. Patients had free choice between the two forms of therapy. SETTING: Patients were treated on an outpatient basis in our department. PATIENTS: Eighteen patients of matched age (mean [+/- SD] age: 21.1 +/- 3.0 years and 23.6 +/- 7.3 years) and similar testicular volume were treated in each group. INTERVENTIONS: Pulsatile GnRH therapy was started with 4 micrograms GnRH subcutaneously every 2 hours using a portable pump and gonadotropin therapy with 3 x 2,500 IU human chorionic gonadotropin (hCG) weekly injected intramuscularly. After 8 to 12 weeks of hCG treatment, 150 IU human menopausal gonadotropin two to four times weekly were added. RESULTS: Testosterone (T) and estradiol (E2) levels increased significantly higher (T: P less than 0.03; E2; P less than 0.001) in the gonadotropin group than in the GnRH group (T: 22.5 +/- 8.1 versus 16.8 +/- 5.5 nmol/L; E2: 150 +/- 70 versus 88. +/- 59 pmol/L). Five patients developed gynecomastia during gonadotropin therapy. The rise of testicular volume was significantly more pronounced (P less than 0.001) in the GnRH group (delta testicular volume = 8.1 +/- 2.0 mL) than in the gonadotropin group (delta testicular volume = 4.8 +/- 1.8 mL). Ten patients of the GnRH and 8 of the gonadotropin group had positive sperm counts, ranging from 1.5 to 26 x 10(6) spermatozoa/mL. The latter was achieved more rapidly in the GnRH group (12 +/- 1.6 versus 20 +/- 2.3 months: P less than 0.02). CONCLUSIONS: Endocrine and exocrine testicular function can be normalized by both forms of therapy. Gonadotropin therapy has more side effects. Gonadotropin-releasing hormone leads to a higher testicular volume and a more rapid initiation of spermatogenesis compared with gonadotropin therapy.

Evaluation of selective transsphenoidal adenomectomy by endocrinological testing and somatomedin-C measurement in acromegaly.

A series of 29 previously untreated patients with acromegaly underwent transsphenoidal adenomectomy. Pre- and postoperative evaluation consisted of measuring growth hormone (GH) secretory dynamics during an oral glucose tolerance test (OGTT), the insulin hypoglycemia test, and the thyrotropin- and gonadotropin-releasing hormone (TRH/GnRH) test, and by obtaining the basal somatomedin-C level. After surgery, clinical and biochemical amelioration was achieved in all but two patients. In the whole group, basal GH and somatomedin-C levels decreased from a mean (+/- standard error of the mean) of 52.3 +/- 12.7 to 11.1 +/- 6.3 ng/ml and from 7.6 +/- 0.7 to 2.5 +/- 0.5 U/ml, respectively. Application of different criteria of cure revealed that 19 patients (66%) had basal GH levels below 5 ng/ml, 17 patients (59%) had normal somatomedin-C values, 16 patients (55%) had complete GH suppression (less than 1 ng/ml) during OGTT, and 13 patients (45%) met the above-mentioned criteria with disappearance of the paradoxical GH response to TRH/GnRH test. Evaluation of GH secretion by insulin hypoglycemia testing was useless in assessing the outcome after neurosurgery. When only patients with a normal somatomedin-C level and complete GH suppressibility during OGTT were considered "cured," the main favorable prognostic factor was intrasellar tumor localization, since 15 (75%) of 20 patients were "cured," as opposed to only one (11%) of nine with extrasellar extension of the adenoma. During the follow-up period, no tumor recurrence was detected in any of the "cured" patients. In these subjects somatomedin-C levels remained stable in all except two patients, who showed a slow increase within the normal range of somatomedin-C concentration. These data confirm that transsphenoidal surgery is the most effective form of treatment in previously untreated acromegalic patients and that normalization of somatomedin-C levels reflects normal GH secretion. Measurement of somatomedin-C could replace more extensive endocrinological testing during monitoring of treated acromegalic patients.

Multistep treatment concept of transsexual patients.

Here we present a pragmatic multistep approach for the treatment of transsexual patients. The importance of an individually designed cross-gender hormone replacement therapy embedded in a multidisciplinary treatment concept, provided by psychiatrists, endocrinologists and surgeons, is demonstrated. Following this concept outcome of therapy has been improved in the last years. Over the last 5 years we have gained substantial experience in the cross-gender hormone treatment of transsexual patients. By continuous follow-up examinations and therapy adjustment the risk of side effects accompanying this therapy has been significantly minimized. This report is designed as a guideline to the clinical endocrinologist for the handling and treatment of transsexual patients.