Gender, body weight, disease activity, and previous radiotherapy influence the response to pegvisomant

CONTEXT/OBJECTIVE: To effectively normalize IGF-I in patients with acromegaly, various covariates may affect dosing and plasma concentrations of pegvisomant. We assessed whether sex, age, weight, and previous radiotherapy influence dosing of pegvisomant in patients with active disease. DESIGN: Data from 69 men and 49 women participating in multicenter, open-label trials of pegvisomant were retrospectively evaluated using multiple regression techniques. Sixty-nine subjects (39 men, 30 women) had undergone external beam pituitary radiotherapy. Serum IGF-I was at least 30% above age-related upper limit of normal in all patients at study entry. After a loading dose of pegvisomant (80 mg), patients were commenced on 10 mg/d. Pegvisomant dose was adjusted by 5 mg every eighth week until serum IGF-I was normalized. RESULTS: At baseline, men had significantly higher mean serum IGF-I levels than women despite similar GH levels. After treatment with pegvisomant, IGF-I levels were similar in men and women. A significant correlation between baseline GH, IGF-I, body weight, and the dose of pegvisomant required to normalize serum IGF-I was observed (all P < 0.001). Women required an average of 0.04 mg/kg more pegvisomant than men and a mean weight-corrected dose of 19.2 mg/d to normalize serum IGF-I [14.5 mg/d (men); P < 0.001]. Patients treated with radiotherapy required less pegvisomant to normalize serum IGF-I despite similar baseline GH/IGF-I levels (15.2 vs. 18.5 mg/d for no previous radiotherapy; P = 0.002). CONCLUSIONS: Sex, body weight, previous radiotherapy, and baseline GH/IGF-I influence the dose of pegvisomant required to normalize serum IGF-I in patients with active acromegaly.     

Growth hormone and pituitary radiotherapy, but not serum insulin-like growth factor-I concentrations, predict excess mortality in patients with acromegaly

Increased mortality in patients with acromegaly has been confirmed in a number of retrospective studies, but causative factors and relationship to serum IGF-I remain uncertain. The West Midlands Pituitary database contains details of 419 patients (241 female) with acromegaly. Serum IGF-I data from the Regional Endocrine Laboratory were available for 360 patients (86%). At diagnosis, mean age was 47 yr (range, 12-84) and mean duration of follow-up was 13 yr (0.5-48). Sixty-one percent were treated by surgery and 39% by nonsurgical means. Radiotherapy was used alone or as adjuvant therapy in 50%. All patients were registered with the Office of National Statistics to obtain information on deaths. At the date of analysis (31 December 2001), 95 of the 419 patients had died (43 males), giving a standardized mortality ratio of 1.26 [confidence interval (CI), 1.03-1.54; P = 0.046]. After controlling for age and sex, data indicated that mortality was increased in subjects with posttreatment GH levels more than 2 micro g/liter, compared with those with levels less than 2 micro g/liter [ratio of mortality rates (RR), 1.55 (range, 0.97-2.50); P = 0.068]. By contrast, a much smaller increase was observed for subjects with elevated posttreatment IGF-I levels compared with those with normal levels [RR, 1.20 (range, 0.71-2.03); P = 0.50]. Treatment with radiotherapy was associated with increased mortality [RR, 1.67 (range, 1.09-2.56); P = 0.018], with cerebrovascular disease the predominant cause of death [standardized mortality ratio, 4.42 (range, 2.71-7.22); P = 0.005]. These results confirm the increased mortality in acromegaly and suggest that reduction of GH levels to less than 2 micro g/liter is beneficial in terms of improving long-term outcome. The sole use of IGF-I as a marker for effective treatment of acromegaly is not justified by this data. This study also highlights the potential deleterious effect of radiotherapy.     

Conventional pituitary irradiation is effective in normalising plasma IGF-I in patients with acromegaly

OBJECTIVE: For patients in whom acromegaly persists despite pituitary surgery, conventional pituitary irradiation represents an additional treatment option. A 30-60% cure rate is described in the literature, but these studies did not utilise strict rules of remission, such as "safe" GH levels <2.5 microg/l, and age-adjusted normal IGF-I levels. DESIGN AND METHODS: We report the outcome of 41 patients with acromegaly who received pituitary conventional external irradiation. The median follow-up time was 12.8 years (3.7-43.4 years) post-radiotherapy. RESULTS: The median pre-irradiation GH level was 31.0 microg/l (7.0-210 microg/l). Information on IGF-I levels was only available for 6 patients prior to therapy. Utilising strict rules of remission, one-third (14/41) of our patients had normal biochemical parameters, i.e. "safe" GH (0.5 microg/l (range 0.2-1.6 microg/l)) and normal age-adjusted IGF-I levels (multiple of upper limit of normal range (xULN); 0.45 (0.2-1.0)) at the end of the follow-up period. An additional 9 patients achieved normal levels with adjunctive drug therapy. Furthermore, disease activity was reduced in a considerable proportion of the 18 patients who did not achieve normal biochemical levels (GH: 3.6 microg/l (1.9-15.7 microg/l); xULN of IGF-I: 1.6 (0.9-2.6)). In retrospect, remission is unlikely in patients who had a GH level greater than 52 microg/l (mean+2 s.d. of cured patients) prior to radiotherapy. In addition to the 12 patients with pre-irradiation pituitary functional deficiency, another 11 patients developed symptoms of panhypopituitarism during the 3-year period following irradiation. Within a 6-year period, partial pituitary insufficiency was observed in a further 7 patients, thus necessitating hormone substitution treatment. CONCLUSION: Using strict rules of remission, in our cohort we found both a normalisation of IGF-I and safe GH levels in 34% of patients treated for acromegaly with conventional irradiation therapy.     

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.     

Long-term follow-up results of postoperative radiotherapy in 36 patients with acromegaly

In acromegaly, pituitary irradiation is a slow, but effective, intervention in decreasing GH concentration. Few studies addressing the outcome of radiotherapy have used the currently accepted strict criteria for remission in the analysis of data. These studies report a low percentage of remission after radiotherapy. Doubt has especially been raised as to whether radiotherapy is effective in normalizing serum insulin-like growth factor (IGF)-I concentration. We analyzed the long-term follow-up data of postoperatively administered radiotherapy in 36 patients with postoperative persistent acromegaly, using both the normalization of GH suppression during oral glucose loading (GTT) and the normalization of IGF-I concentration as criteria for remission. Before radiotherapy, mean suppressed GH was 9.8 +/- 1.9 mU/L (n = 31), and mean IGF-I concentration was 44.3 +/- 3.9 nmol/L, equivalent to + 4.76 +/- 0.78 age-related IGF-I SD score (n = 13). The median radiation dose was 40 Gray (range, 25-50 Gray). At 5, 10, and 15 yr follow-up, 18 out of 30 patients (60%), 23 out of 31 patients (74%), and 16 out of 19 patients (84%), respectively, achieved normal serum IGF-I concentration. At the last assessment of all patients, after a mean follow-up period of 139 +/- 12 months, 27 out of 36 (75%) patients had a normal IGF-I concentration without additional medication, whereas 5 patients still required treatment with octreotide. Remission, as judged by normalization of GH suppression during GTT, was documented in 65% of patients from 2-5 yr after radiotherapy (n = 34); in 69% of patients, up to 10 yr after radiotherapy (n = 29); and in 71% of patients, up to 15 yr post irradiation (n = 17). At the latest assessment, a mean of 125 +/- 11 months after radiotherapy, 71% of patients (n = 35) were in remission, as defined by normal suppression of serum GH during GTT. Remission, as judged by normalization of both GTT and IGF-I, was found in 40% of patients 3-5 yr after radiotherapy (n = 30); in 61% of patients, 6-10 yr after radiotherapy (n = 28); in 65%, after 11-15 yr after radiotherapy (n = 17); and in 63% of patients, at the end of the follow-up period (n = 35). Substitution of one or more pituitary hormone deficiencies was required in 11% of patients postoperatively; in 29%, 5 yr after radiotherapy; in 54%, 10 yr after radiotherapy; and in 58%, more than 15 yr after radiotherapy. Our findings support the use of radiotherapy as an effective intervention in the treatment of residual clinical activity of disease after surgery for acromegaly.     

An audit of long-term octreotide therapy for acromegaly

Abstract Background: Octreotide has been successfully used for the treatment of acromegaly, but little long-term data are available.
Aims: To determine the long-term efficacy and safety of octreotide in the treatment of acromegaly.
Methods: Twenty-seven patients with acromegaly were treated with octreotide in a non randomised study. Six patients had not had previous surgery or radiotherapy, and were treated with octreotide alone. Symptoms of acromegaly, IGF-I levels, growth hormone suppression by glucose, pituitary tumour size, and side effects were monitored. The median duration of treatment was 44 months (range six-102).
Results: Symptom control was excellent. Twenty (74%) patients had a reduction of IGF-I into the normal range. IGF-I levels fell after one year from 94.2±6.1 nmol/L (mean±SEM) to 50.0±2.7 nmol/L ( p <0.0001). Ten of 13 (77%) patients had normal IGF-I levels after four years. These reductions have persisted for up to nine years of octreotide therapy. The GH response to glucose was normalised in 14 of 16 (88%) subjects. Eleven of 25 (44%) patients had a reduction in pituitary gland height. Side effects were common, but usually of a minor nature. Cholelithiasis occurred in 39% of patients. Two patients ceased octreotide because of side effects.
Conclusions: We conclude that octreotide is an effective and safe long-term treatment for acromegaly. It is a useful adjunct to surgery, and may be offered as sole therapy for patients with smaller adenomas.     

Effectiveness of adding dopamine agonist therapy to long-acting somatostatin analogues in the management of acromegaly

BACKGROUND: The excess mortality and morbidity associated with acromegaly are secondary to prolonged elevation of GH and IGF-I. Vigorous control of these biochemical parameters results in improved morbidity and mortality. Somatostatin analogues (SAs) allow adequate control of GH and IGF-I in approximately 65% of subjects, leaving a significant cohort uncontrolled. Dopamine agonists (DAs), a cheap alternative to SAs, allow control of GH and IGF-I in less than 20% of patients with acromegaly. AIMS: To assess the effectiveness of adding DA therapy to SA in the biochemical control of acromegaly. SUBJECTS: One hundred and twenty cases from the Sheffield Acromegaly Register were reviewed; 24 (20%) did not require medical treatment following pituitary surgery alone; 16 (13%) had safe GH levels following surgery and radiotherapy; and 58 (48%) required medical treatment despite having had surgery, radiotherapy or both. The remaining 22 (18%) received only medical treatment. METHODS: In nine subjects a DA (three bromocriptine, six cabergoline) was added to an SA to control active disease. GH day curves and IGF-I levels were compared before and after the addition of a DA to existing SA treatment. All were on stable maximum-dose treatment with an SA, with inadequate biochemical control prior to addition of DA therapy. Mean duration of treatment on a DA before biochemical assessments were made was 10.3 months. Six subjects had previously been treated with either transsphenoidal surgery, radiotherapy or both. In three subjects SA was the primary therapy. RESULTS: All subjects exhibited a fall in median GH and IGF-I levels. Introduction of a DA resulted in a 36.1% reduction in median GH levels (8.3 vs 5.3 mIU/l; P = 0.008) on a GH day curve and a 35.2% reduction in IGF-I levels (387.2 vs 251.0 microg/l; P = 0.018). Only four subjects had elevated prolactin levels prior to the addition of a DA (>368 mIU/l). CONCLUSION: Addition of DAs to SAs is of benefit in the biochemical control of acromegaly and should be considered in those inadequately controlled. Furthermore, the beneficial effects of DAs occur even when pre-treatment prolactin levels are within the normal range.     

Gender and age influence the relationship between serum GH and IGF-I in patients with acromegaly

BACKGROUND: In patients with acromegaly serum IGF-I is increasingly used as a marker of disease activity. As a result, the relationship between serum GH and IGF-I is of profound interest. Healthy females secrete three times more GH than males but have broadly similar serum IGF-I levels, and women with GH deficiency require 30-50% more exogenous GH to maintain the same serum IGF-I as GH-deficient men. In a selected cohort of patients with active acromegaly, studied off medical therapy using a single fasting serum GH and IGF-I measurement, we have reported previously that, for a given GH level, women have significantly lower circulating IGF-I. OBJECTIVE: To evaluate the influence of age and gender on the relationship between serum GH and IGF-I in an unselected cohort of patients with acromegaly independent of disease control and medical therapy. METHODS: Sixty (34 male) unselected patients with acromegaly (median age 51 years (range 24-81 years) attending a colonoscopy screening programme were studied. Forty-five had previously received pituitary radiotherapy. Patients had varying degrees of disease control and received medical therapy where appropriate. Mean serum GH was calculated from an eight-point day profile (n = 45) and values obtained during a 75-g oral glucose tolerance test (n = 15). Serum IGF-I, IGFBP-3 and acid-labile subunit were measured and the dependency of these factors on covariates such as log10 mean serum GH, sex, age and prior radiotherapy was assessed using regression techniques. RESULTS: The median calculated GH value was 4.7 mU/l (range 1-104). A significant linear association was observed between serum IGF-I and log10 mean serum GH for the cohort (R = 0.5, P < 0.0001). After simultaneous adjustment of the above covariates a significant difference in the relationship between mean serum GH and IGF-I was observed for males and females. On average, women had serum IGF-I levels 11.44 nmol/l lower than men with the same mean serum GH (P = 0.03, 95% CI 1.33-21.4 nmol/l). Age significantly influenced the relationship and for a given serum GH, IGF-I was estimated to fall by 0.37 nmol/l per year (P = 0.04, 95% CI 0.015-0.72). CONCLUSIONS: In keeping with previous observations of relative GH resistance in normal and GH-deficient females we have observed lower serum IGF-I levels for equivalent mean serum GH levels in females patients with acromegaly. This gender-dependent difference is independent of disease activity and the use of concomitant medical therapy. Additionally, we have demonstrated that for a given serum GH level, age significantly influences IGF-I concentrations in patients with acromegaly. These data have important implications for the use of serum IGF-I and GH as markers of disease activity in acromegaly.     

New therapeutic options for acromegaly

Acromegaly is a slowly developing disfiguring disease characterized by chronic growth hormone (GH) and insulin-like growth factor-I (IGF-I) excess and caused by a pituitary somatotroph adenoma. It is associated to 2- to 3 fold increased mortality, compared to normal population, mostly due to cardiovascular and cerebro-vascular diseases, and to several co-morbid systemic illnesses, such as diabetes mellitus, hypertension, severe arthropathies, a specific cardio-myopathy, goitre, sleep-apnoea, intractable headache. The morbidity and excess mortality of acromegaly are usually the consequence of the metabolic actions of excess GH and IGF-I secretion, while only in rare patients mortality is due to the mass effects of the pituitary tumour. Since, serum IGF-I concentrations within age-adjusted normal range, and a tight GH control have to be achieved to normalize life-expectancy in these patients, an aggressive, and often multi-modality treatment is required for acromegaly. In recent years, new drugs, and new formulations of old drugs, have been developed that are able to effectively inhibit GH secretion or GH action, and may represent important adjuncts or even alternatives to the traditional approaches of surgery and radiotherapy. This review briefly summarizes the therapeutic options nowadays available for acromegaly. A brief note about innovative drugs under study, is also given.     

Dynamic tests and basal values for defining active acromegaly

Acromegaly is a rare disease caused by excess secretion of growth hormone (GH), usually from a pituitary somatotrope adenoma. The prevalence of acromegaly is 38-40 cases/1,000,000 subjects, while the annual incidence is 3 new cases/1,000,000 subjects. The increase in morbidity and mortality associated with acromegaly is the result of GH and insulin-like growth factor (IGF)-I oversecretion and the direct mass effect of the pituitary tumor. Once the disease is clinically suspected, laboratory evaluation is mandatory to establish diagnosis. The standard method for the diagnosis of acromegaly has been the measuring of GH nadir (GHn) during an oral glucose tolerance test (OGTT) which in normal individuals is undetectable, while acromegalics failed to suppress GH levels. Determination of IGF-I levels is useful as they correlate with clinical features of acromegaly and with the 24-hour mean GH levels. According to the more recent consensus, a random GH <0.4 microg/l and IGF-I in the age- and gender-matched normal range exclude the diagnosis of acromegaly. If either of these levels are not achieved, an OGTT should be performed, and then GHn <1 microg/l during OGTT excludes acromegaly. The therapeutic goals for acromegaly include the relief of sings and symptoms, the control of the tumor mass, the correction of the biochemical markers to normal levels, and the reduction in morbidity and mortality to the expected rate for the normal population. According to the 2000 consensus criteria, biochemical control of acromegaly is achieved when circulating IGF-I is reduced to an age- and sex-adjusted normal range and GHn during OGTT is <1 microg/l. There is debate in the literature whether GHn or IGF-I levels are more reliable to evaluate treatment of acromegaly. It has been reported that 15% of acromegalics with GHn <1 microg/l after treatment demonstrate abnormal IGF-I levels, while 15% of patients with normal IGF-I fail to suppress GH levels <1 microg/l during the OGTT. Probably, GHn and IGF-I levels represent two different aspects of disease activity in acromegaly. While IGF-I evaluates the secretory function of the somatotropes, GHn provides evidence of the presence or absence of functional autonomy of these cells.     

A nationwide survey of mortality in acromegaly

CONTEXT: Increased mortality in acromegaly has been confined to those with posttreatment basal GH of 2.5 microg/liter or greater, but the impact of IGF-I and pituitary radiotherapy on mortality has remained controversial. OBJECTIVE: The purpose of this nationwide survey was to examine the all-cause mortality of patients with acromegaly and evaluate the impact of treatment outcome and mode of treatment on survival. DESIGN, SETTING, AND PATIENTS: All-cause mortality of all patients with acromegaly diagnosed during January 1980 and December 1999 in the five university hospitals of Finland was followed up by the end of 2002 (12.5 +/- 5.6 yr) and compared with that of the general population by using age- and gender-adjusted standardized mortality ratios (SMRs). Logistic regression analysis was used to investigate factors related to mortality within the survey population. MAIN OUTCOME MEASURE: Mortality was the main outcome measure. RESULTS: Of the 334 patients, 56 (16.8%) had died during follow-up. SMR of the patients was 1.16 [confidence interval (CI) 0.85-1.54, not significant (NS)]. However, patients with basal serum GH concentration 2.5 microg/liter or greater (SMR 1.63, CI 1.10-2.35, P < 0.001) measured 5.2 +/- 4.4 yr after the initial treatment, and those irradiated (SMR 1.69, CI 1.05-2.58, P < 0.001) showed excess mortality. In a multivariate model, the effect of radiotherapy was of borderline significance only (P = 0.083). Posttreatment IGF-I levels, available for 72.2% of the patients, did not have impact on mortality. CONCLUSIONS: The posttreatment basal GH concentration less than 2.5 microg/liter in acromegalic patients is associated with a normal lifespan. Excess mortality is confined to poorly controlled patients and possibly those who have received conventional radiotherapy.     

Partial surgical removal of growth hormone-secreting pituitary tumors enhances the response to somatostatin analogs in acromegaly

CONTEXT: Surgery is a cornerstone in the treatment of acromegaly, but its efficacy in large, invasive tumors is scant. OBJECTIVE: The objective of this study was to investigate whether partial surgical removal of GH-secreting pituitary tumors enhances the response rate to somatostatin analogs (SSA; sc octreotide, slow-release octreotide, and lanreotide). DESIGN: This was a multicenter, open, retrospective study. SETTING: The study was performed at university hospitals. SUBJECTS AND METHODS: Eighty-six patients (42 women and 44 men; age, 42 +/- 14 yr) with acromegaly were studied. INTERVENTIONS: Patients underwent two courses of octreotide, lanreotide, or slow-release octreotide treatments before and after surgery of at least 6 months. MAIN OUTCOME MEASURE: The main outcome measure was normal IGF-I levels for age. RESULTS: Presurgical SSA treatment significantly decreased GH and IGF-I levels in all patients. GH levels were less than 2.5 microg/liter in 12 patients (14%); IGF-I levels normalized in nine (10%). After surgery, GH and IGF-I levels further decreased in all patients; tumor removal was greater than 75% in 50 (58%), 50.1-75% in 21 (24%), 25.1-50% in 10 (12%), and less than 25% in five patients (6%). Preoperatively, pituitary function was impaired in 12 patients (14%). Postsurgical SSA treatment lowered GH levels to less than 2.5 microg/liter in 49 (56%) and normalized IGF-I levels in 48 patients (55%). The success rate was significantly increased compared with that before surgery (P < 0.0001). GH (r = -0.48; P < 0.0001) and IGF-I levels (r = -0.38; P = 0.0003) after postsurgery SSA treatment correlated with the amount of tumor surgically removed. After surgery, pituitary function was impaired in 28 patients (32.6%) and was improved in 12 patients (13.9%). The cumulative prevalence of pituitary deficiency did not change during the study (normal function from 40 to 42%; deficiency from 60 to 58%). CONCLUSIONS: Surgical tumor removal (>75%) enhances the response to SSAs without impairing pituitary function. Our data indicate that surgical debulking has a significant place in the treatment algorithm of acromegaly.     

Cardiac and metabolic effects of chronic growth hormone and insulin-like growth factor I excess in young adults with pituitary gigantism

Chronic growth hormone (GH)/insulin-like growth factor I (IGF-I) excess is associated with considerable mortality in acromegaly, but no data are available in pituitary gigantism. The aim of the study was to evaluate the long-term effects of early exposure to GH and IGF-I excess on cardiovascular and metabolic parameters in adult patients with pituitary gigantism. Six adult male patients with newly diagnosed gigantism due to GH secreting pituitary adenoma were studied and compared with 6 age- and sex-matched patients with acromegaly and 10 healthy subjects. Morphologic and functional cardiac parameters were evaluated by Doppler echocardiography. Glucose metabolism was assessed by evaluating glucose tolerance and homeostasis model assessment index. Disease duration was significantly longer (P<.05) in patients with gigantism than in patients with acromegaly, whereas GH and IGF-I concentrations were comparable. Left ventricular mass was increased both in patients with gigantism and in patients with acromegaly, as compared with controls. Left ventricular hypertrophy was detected in 2 of 6 of both patients with gigantism and patients with acromegaly, and isolated intraventricular septum thickening in 1 patient with gigantism. Inadequate diastolic filling (ratio between early and late transmitral flow velocity<1) was detected in 2 of 6 patients with gigantism and 1 of 6 patients with acromegaly. Impaired glucose metabolism occurrence was higher in patients with acromegaly (66%) compared with patients with gigantism (16%). Concentrations of IGF-I were significantly (P<.05) higher in patients with gigantism who have cardiac abnormalities than in those without cardiac abnormalities. In conclusion, our data suggest that GH/IGF-I excess in young adult patients is associated with morphologic and functional cardiac abnormalities that are similar in patients with gigantism and in patients with acromegaly, whereas occurrence of impaired glucose metabolism appears to be higher in patients with acromegaly, although patients with gigantism are exposed to GH excess for a longer period.     

The long-term efficacy of conventional radiotherapy in patients with GH-secreting pituitary adenomas

OBJECTIVE: To assess the long-term efficacy and safety of conventional radiotherapy (RT) in the control of acromegaly according to recent stringent criteria of cure. DESIGN: A retrospective longitudinal study. PATIENTS AND METHODS: Forty-seven patients with active acromegaly were treated with conventional RT between 1982 and 1994. All patients were first operated on and successively irradiated at a dose of 45-50 Gy in 25-28 fractions for persistent (n = 40) or recurrent (n = 7) disease. MEASUREMENTS: Long-term GH/IGF-I secretion and local tumour control were evaluated regularly, and possible side-effects were searched for systematically, especially in terms of secondary endocrine dysfunction. Biochemical cure of acromegaly was defined by glucose-suppressed plasma GH levels below 1 microg/l during an oral glucose tolerance test (OGTT) and normal age-corrected IGF-I values. RESULTS: The 5-, 10- and 15-year overall survival rates were 98%, 95% and 93%, respectively. Suppression of GH during OGTT was seen in 9% of patients at 2 years, 29% at 5 years, 52% at 10 years, and 77% at 15 years. Age-corrected IGF-I levels were normal in 8% of patients 2 years after RT, and this proportion increased to 23%, 42% and 61% after 5, 10 and 15 years, respectively. Normalization of GH/IGF-I mainly depended on pre-RT levels. Local tumour control was 95% at 5, 10 and 15 years after treatment. Late toxicity was mainly represented by progressive hypopituitarism, which was present in 33% of patients at baseline and increased to 57%, 78% and in 85% of patients at 5 10 and 15 years after RT, respectively. CONCLUSION: Conventional RT is effective in the long-term control of GH-secreting pituitary adenomas, although with a high prevalence of progressive hypopituitarism. At present, it remains a suitable option in acromegalic patients uncontrolled by surgery or medical therapy.     

Serum IGF-I levels in the diagnosis and monitoring of acromegaly

Insulin-Like Growth Factor-I (IGF-I) is a reliable marker of disease activity and growth hormone (GH) status in acromegaly, but its clinical utility has been hampered over the years by various issues including a lack of robust reference range data and variability in assay sensitivity and specificity. In acromegaly IGF-I correlates well with GH activity and nadir GH on oral glucose tolerance test (OGTT) and is the most sensitive and specific test in diagnosis, where serum IGF-I is persistently seen to be elevated to a range that is distinct from that in healthy individuals. However it should not be relied on exclusively for diagnosis or used as the sole indication of disease severity and GH burden. Successful medical or surgical treatment of acromegaly is usually associated with normalisation of serum IGF-I but there is discordance between GH and IGF-I in some patients. Patients with a normal IGF-I but an abnormal GH suppression to OGTT are at risk of relapse and therefore it should not be used alone to establish disease remission. In contrast to the diagnosis of acromegaly, there is also considerable overlap in serum IGF-I with normality after primary treatment of disease, even in the presence of persisting GH excess. Gender, age and prior radiotherapy alters the relationship between GH and IGF-I and reliance on one marker of disease activity such as IGF-I is particularly precarious in certain disease states. However an elevated serum IGF-I has been shown to be associated with excess mortality and normalising IGF-I normalises mortality making it a useful marker. The tightening up of the assays means that establishing absolute concentrations as well as standard deviation scores are essential to allow cross-study comparisons. This becomes especially important in the use of Pegvisomant, where IGF-I becomes the sole biochemical marker of disease activity.     

Stereotactic radiosurgery XVI: a treatment for previously irradiated pituitary adenomas

We report the use of stereotactic radiosurgery delivered through an adapted linear accelerator [stereotactic multiple arc radiation therapy (SMART)] for pituitary adenomas not cured by conventional therapy. All 21 patients had undergone conventional radiotherapy (45-50 Gy); 18 had also undergone prior surgery. This cohort comprised 13 patients with somatotrope adenomas, four with corticotrope adenomas, one with a lactotrope adenoma, and three with nonfunctioning pituitary adenomas (median follow-up: 33 months, range: 3-72 months). SMART has proven effective, safe, and rapidly acting. We observed an accelerated reduction in GH and IGF-I levels in acromegaly, with normalization of GH and IGF-I levels in 58%. Mean GH fell from 21.1 mU/liter to 7.9 mU/liter (7 ng/ml to 2.6 ng/ml, P < 0.01, median 25 months) faster than our predicted fall to 50% at 2 yr with conventional radiotherapy. Mean IGF-I fell from 624 ng/ml to 384 ng/ml (P < 0.001). Tumor growth was controlled in two of three nonfunctioning pituitary adenomas, and three of four corticotrope adenomas. There were no adverse effects from SMART. Notably there have been no visual sequelae or further loss of anterior pituitary function in this heavily pretreated group. Our data indicate that SMART is an effective complementary therapy for pituitary adenomas that have displayed a suboptimal response to conventional therapy including external irradiation.     

Long-term treatment of acromegaly with the somatostatin analogue SR-lanreotide.

OBJECTIVE: To assess the efficacy and tolerability of SR-lanreotide in the treatment of active acromegaly. PATIENTS AND DESIGN: 30 patients (17 men and 13 women) were treated in whom active acromegaly was confirmed by clinical features, a mean GH level of >5 mlU/l and failure to suppress GH to <2 mlU/l after a 75 g glucose load. Patients were treated for a median period of 60 weeks (range 12-168) with im injections of SR-lanreotide 30 mg given every 7-14 days. MEASUREMENTS: Mean GH and IGF-I levels were measured at baseline and every 12-weeks together with symptom score assessment. MRI of the pituitary gland was performed at baseline and if an adenoma was identified at yearly intervals. Gall bladder ultrasound scans were performed at baseline and then every 24-weeks. RESULTS: Twenty-three patients were treated for at least 48-weeks and, in these, GH levels fell from 10.5 mlU/l (7.6-17.6) (median and interquartile range) at baseline to 3.2 mlU/l (2.4-3.9) (p<0.0001) and IGF-I levels ftom 88.9 nmol/L (71.4-137.1) to 56.8 nmol/l (39.3-75.4) (p=0.0002). GH response to treatment was better in elderly patients (age> or =65 years) compared to younger patients but neither sex, pre-treatment GH levels, previous surgery nor previous radiotherapy influenced the response. Treatment resulted in a significant improvement in the symptoms of active acromegaly in the majority of patients. A significant reduction in the size of the pituitary adenoma was documented in 6 of 10 patients who had a repeat MRI scan after one year. Treatment was well-tolerated by the majority of patients; side effects were mainly transient gastrointestinal symptoms. These were severe in only 2 patients necessitating discontinuation of the drug. Two patients developed new gall stones and 4 female patients had temporal hair loss necessitating stopping treatment in one of them. There were minor effects on glucose tolerance which were not of clinical importance. CONCLUSION: Long-term treatment of acromegaly with SR-lanreotide is effective in controlling GH and IGF-I levels and symptoms and is well tolerated in the majority of patients.     

Efficacy of radiotherapy in normalizing serum IGF-I, acid-labile subunit (ALS) and IGFBP-3 levels in acromegaly

OBJECTIVE: Radiotherapy (RT) has been used for many years in order to complete the cure of unsuccessfully operated acromegalic patients. Several studies have shown its efficacy in normalizing GH levels, while reports about IGF-I normalization are conflicting. Moreover, data regarding other markers of disease activity, such as IGFBP-3 and acid-labile subunit (ALS), i.e. the other two components of the circulating 150 kDa complex, are lacking. DESIGN: Retrospective study. PATIENTS AND MEASUREMENTS: Sixty-seven acromegalic patients (20 males and 47 females, aged 40 +/- 6 years) who underwent postoperative RT (in fractionated doses for a total of 40-75 Gy) were followed-up for 11 +/- 6 years (range: 1-26 years, median: 10 years). Serum GH and IGF-I levels off medical therapy were measured in all patients; ALS and IGFBP-3 were measured in 11 patients with normalization of IGF-I concentrations. Computed tomography or nuclear magnetic resonance imaging periodically assessed possible development of pituitary deficiency along with imaging of the hypothalamic-pituitary region. RESULTS: Forty-one out of 67 patients (58%) achieved GH levels < 2.5 microg/l by 1-15 years after RT (mean 8 +/- 6) and 37/67 patients (55%) had normal or low IGF-I levels 1-26 years after RT (mean: 12 +/- 6), a normalization of both parameters being seen in 37 patients. GH < 2.5 microg/l and normal IGF-I levels were achieved in 17/26 (65%) patients followed-up for at least 15 years. ALS and IGFBP-3 concentrations paralleled IGF-I levels in all patients studied. With respect to secondary pituitary insufficiency, acquired ACTH deficiency was found in 25 patients, TSH deficiency in 20, gonadotropin deficiency in 23 and GH deficiency in seven. In total, two cases of meningioma and one pineal tumour, possibly related to RT, were seen 9-22 years after RT. CONCLUSIONS: RT is an effective, although slow-acting, therapeutic tool for acromegaly, with 'safe' GH levels and normal IGF-I concentrations being achieved in 65% of patients after 15 years. IGF-I levels normalize more slowly than GH levels. Radiotherapy is able to normalize the concentration of all three components of the circulating 150 kDa complex. Checks for loss of pituitary function and appearance of second brain tumours must be carried out life-long.     

Assessment of disease activity in treated acromegalic patients using a sensitive GH assay: should we achieve strict normal GH levels for a biochemical cure?

The definition of a cure for acromegaly is controversial in the absence of a well-defined clinical end-point. Therefore, cure in acromegaly may be arbitrarily defined as a normalization of biochemical parameters. The accepted normal GH levels have been modified over time with the improved sensitivity of GH assays. The objective of the present study was to investigate the suppression of GH levels in the oral glucose tolerance test (oGTT) using a sensitive GH immunoassay in a large group of normal adult subjects and treated acromegalic patients. We evaluated these results in conjunction with IGF-I and IGF binding protein 3 (IGFBP-3) levels. Nadir GH levels after the ingestion of 75 g of glucose, as well as baseline IGF-I and IGFBP-3 levels, were evaluated in 56 normal adult subjects and 32 previously treated acromegalic patients. GH was assayed by an immunofluorometric assay. Normal controls had a mean GH nadir of 0.07 +/- 0.09 microg/liter. Their mean basal IGF-I and IGFBP-3 levels were 160 +/- 58 microg/liter and 1926 +/- 497 microg/liter, respectively. Acromegalic patients had mean GH nadir, IGF-I, and IGFBP-3 levels higher than those of normal subjects (2.6 +/- 7.6 microg/liter, 313 +/- 246 microg/liter, and 2625 +/- 1154 microg/liter, respectively). Considering a GH cut-off value of 0.25 microg/liter, as the normalized postglucose GH upper limit (mean + 2 SD) and, therefore, the target for treated patients, only five patients (15.6%) would have been considered cured. These results suggest that the strict physiological normalization of GH levels after oGTT is not often achieved as a therapeutic endpoint in acromegaly. In addition to the refinement of GH assays, epidemiological studies have suggested that the mean basal GH levels (<2.5 microg/liter) or oGTT-derived GH levels < 2 microg/liter (RIA), or the normalization of IGF-I levels, appear to reduce morbidity and mortality in treated acromegaly. Using this epidemiologically based definition of cure for acromegaly, we reviewed our results obtained with a sensitive GH assay. Twenty-five patients (78%) had oGTT nadir GH < 2 microg/liter. Nineteen subjects had normal age-related IGF-I levels. When the GH nadir cut-off was reduced to 1 microg/liter or less, there was a cure rate of 59.4%. IGF-I and IGFBP-3 levels were normal in 16 and 15 of these 19 patients, respectively. Furthermore, 59.4% of these 32 patients were in remission when age-normalized IGF-I levels were used as a criterion for inactive disease. All but three had GH nadir of 1 microg/liter or less. Finally, the definition of cure may be contradictory in a subgroup (9.4%) of patients with a GH nadir less than 1 microg/liter despite high-for-age IGF-I levels. In conclusion, using a sensitive GH assay it can be seen that the strictly normal postglucose GH values less than 0.25 microg/liter required for biochemical control of acromegaly are not often achieved. Furthermore, the cut-off of GH nadir 1 microg/liter or less is more closely related to normal for age serum IGF-I levels in treated acromegalic patients than 0.25 microg/liter or 2 microg/liter cut-offs. According to previous epidemiological reports, a GH level less than 2.5 microg/liter, determined by RIA, is associated with a reduction of morbidity and mortality. Therefore, our data lead us to postulate that the biochemical criterion of oGTT GH levels 1 microg/liter or less, determined by immunofluorometric assay, is a useful and accurate marker of safe GH secretion in treated acromegaly.     

The relationship between 24-hour growth hormone secretion and insulin-like growth factor I in patients with successfully treated acromegaly: impact of surgery or radiotherapy

In patients with treated acromegaly, improved survival is associated with serum GH concentrations below 2 microgram/L (5 mU/L). A principal aim of therapy in acromegaly is to achieve a GH level less than 2 microgram/L, as such levels are thought to be "safe." However, such GH levels do not always equate with normalization of plasma insulin-like growth factor I (IGF-I), although epidemiological data linking survival or morbidity to IGF-I levels are at present lacking. The aims of this study were 1) to further define the nature of GH release in those acromegalic patients who achieve mean GH concentrations below 2 microgram/L post therapy, 2) to examine the effect of different therapeutic interventions on the 24-h GH profile (surgery alone or radiotherapy), and 3) to determine the relationship between the various characteristics of the 24-h GH profile and IGF-I production in acromegalic subjects who have achieved GH below 2 microgram/L. Spontaneous 24-h GH secretion was measured using both a conventional immunoradiometric assay (limit of detection, 0.4 microgram/L) and an ultrasensitive assay (limit of detection, 0.002 microgram/L). The GH data have been analyzed by several methods: 1) the pulse detection algorithm Cluster, 2) a distribution method for detection of peak [the observed concentration 95%, i.e. the threshold at or below which GH concentrations are assessed to be 95% of the time, as calculated by probability analysis (OC 95%)] and trough (OC, 5%) GH activity, 3) deconvolution analysis, and 4) approximate entropy analysis. GH was sampled every 20 min for 24 h, along with basal IGF-I and IGF-binding protein-3, in 21 treated acromegalic patients with a mean GH below 2 microgram/L [ACR; 9 women and 12 men; median age (range), 49 (31-76) yr] and 16 healthy controls [C; 6 women and 10 men; age, 50 (30-75) yr]. Mean 24-h serum GH concentrations were [median (range)]: ACR, 1.1 (0.04-1.5) microgram/L; C, 0.4 (0.02-3.3) microgram/L (P = 0.28). GH pulse frequency was: ACR, 11 (1-14)/24 h; C, 10 (8-18)/24 h (P = 0.41). In the GH profiles the mean heights of the GH peaks were: ACR, 1.2 (0.05-2.8) microgram/L; C, 0.8 (0.02-5.1) microgram/L (P = 0.91), and the mean GH valley nadirs were: ACR, 0.65 (0.03-1.1) microgram/L; C, 0.09 (0.01-1.8) microgram/L (P < 0.02). The OC 95% was: ACR, 1.0 (0.04-3.8) microgram/L; C, 1.0 (0.02-10) microgram/L (P = 0.65), and the OC 5% was: ACR, 0.09 (0.01-0.6) microgram/L; C, 0.01 (0.001-0.4) microgram/L (P < 0.001). The median IGF-I was: ACR, 227 (100-853) microgram/L; C, 156 (89-342) microgram/L (P < 0.005). Approximate entrophy values were: ACR, 1.06 (0.35-1.45); and C, 0.57 (0.27-1.19); P < 0.05. In the acromegaly group a significant positive correlation was found between IGF-I and the calculated GH secretory burst amplitude in the radiotherapy subset (r = 0.85; P < 0.0005) as well as between IGF-I and both the mean GH valley nadir (r = 0.60; P < 0.004) and the trough (OC 5%) GH activity for the acromegalic patients as a whole (r = 0.55; P < 0.02). We conclude that in treated acromegaly (GH, <2 microgram/L), 1) IGF-I (by approximately 50%) and basal GH secretion (by 5-fold) remain significantly elevated compared with control values despite similar mean 24-h GH concentrations; 2) the calculated GH secretory pulse amplitude, mean GH valley nadir, and OC 5% correlate positively with IGF-I; 3) the greater mean GH valley nadir and OC 5% in acromegalic patients compared with controls may account for the raised IGF-I; and 4) radiotherapy is unlikely to normalize the GH secretory pattern, which underlies the persisting elevated IGF-I levels.