Growth hormone treatment in adults with adult-onset growth hormone deficiency increases iliac crest trabecular bone turnover: a 1-year, double-blind, randomized, placebo-controlled study.

The effects of growth hormone (GH) substitution on bone metabolism were evaluated by dynamic histomorphometry on iliac crest bone biopsies. Twenty-nine patients, aged 21-61 years (mean 45.5 years), with adult-onset GH deficiency (GHD) were randomized to receive subcutaneous injections with GH (2 IU/m2/day = 0.67 mg/m2/day) or placebo for 12 months. Serum insulin-like growth factor I (IGF-I) levels increased 263 +/- 98% (mean +/- SD) during GH treatment (p < 0.0001). In the GH group, osteoid surface increased during treatment from 11% (3-15%) (median [25-75 percentiles]) to 21% (10-27%) (p = 0.01) and mineralizing surface from 4% (1-8%) to 11%(7-16%) (p = 0.04). Moreover, erosion surface tended to increase in the GH group from 2% (1-3%) to 4% (3-5%) (p = 0.07). The quiescent surface decreased in the GH group from 87% (83-96%) to 74% (68-87%) (p = 0.01). The adjusted appositional rate, mineral apposition rate, bone formation rate, bone erosion rate, mineralization lag time, and osteoid thickness remained unchanged during treatment. Erosion depth showed a trend toward increase in the GH group (p = 0.09), whereas wall thickness was unchanged. Bone balance at the remodeling unit level and activation frequency were unchanged. At the tissue level, bone erosion rate increased significantly from 26% (17-36%)/year to 39% (23-72%)/year (p = 0.03). Similarly, the bone formation rate at the tissue level tended to increase, from 24% (15-31%)/year to 36% (17%-63%)%/year (p = 0.06). Finally, bone balance at the tissue level decreased significantly from 1% (-2-2%)/year to -5% (-13-1%)/year (p = 0.01). No significant difference in change was seen in the cancellous bone volume. We conclude that 12 months of GH substitution therapy increases trabecular bone turnover. Moreover, our data suggest that bone balance at the bone multicellular unit level is not changed to positive.

Abdominal adiposity and physical fitness are major determinants of the age associated decline in stimulated GH secretion in healthy adults.

Growth hormone (GH) secretion is reduced with age in normal subjects. Aging is furthermore associated with a decline in lean body mass and an increase in relative adiposity, and overt obesity is a negative determinant of GH secretion in all age groups. We tested the hypothesis that differences in body composition and physical fitness rather than age determine stimulated GH secretion in healthy adults. Forty-two clinically nonobese adults [22 women and 20 men, mean age 39.4 yr (range 27-59), mean +/- SE body mass index (BMI) = 23.9 +/- 0.5 kg/m2] underwent 2 GH stimulation tests (arginine and clonidine), determination of maximal oxygen consumption (VO2-max), and a number of anthropometric measurements: body mass index (BMI), waist to hip (W/H)-ratio, intraabdominal fat and thigh muscle to fat (M/F)-ratio (computed tomography scan), total body fat, and lean body mass (DEXA scan). Peak GH levels were lower with clonidine [mean +/- SE (micrograms/L): 9.79 +/- 1.29 (arginine) vs. 3.56 +/- 0.57 (clonidine) (P < 0.001)]. Arginine-stimulated GH peak levels correlated negatively with indices of adiposity and age [intraabdominal fat: r = -0.72, P < 0.001; W/H-ratio: r = -0.58, P < 0.001; age: r = -0.54, P < 0.001], and positively with VO2-max [r = 0.60, P < 0.001]. Clonidine-stimulated GH peak correlated negatively with intraabdominal fat [r = -0.60, P < 0.001] and age [r = -0.46, P = 0.008]. Multiple linear regression revealed multicollinearity among several of the independent variables. In all equations abdominal adiposity and physical fitness, rather than age, contributed significantly to predict changes in arginine stimulated GH secretion. Intraabdominal fat was a more important determinant of the clonidine evoked GH response than age. In clinically nonobese, healthy adults relative adiposity, in particular in the abdominal region, is a major negative determinant of stimulated GH secretion, and physical fitness is an important positive predictor. The cause-effect relationship of these observations remains to be elucidated, but our findings may have clinical implications in the diagnosing of GH-deficiency in adults.

Continuation of growth hormone (GH) replacement in GH-deficient patients during transition from childhood to adulthood: a two-year placebo-controlled study.

Previous studies have demonstrated beneficial effects of GH replacement, in adults with GH deficiency (GHD), on body composition, physical fitness, and quality of life. These studies, however, concern patients with adult-onset GHD or childhood-onset (CO) patients enrolled several years after withdrawal of initial therapy. So far, the effects of continuation of GH-administration in patients with CO-GHD have not been examined. We studied a group of nineteen young adults (13 males + 6 females; 16-26 yr old; mean age, 20.2 +/- 0.65 yr) with CO-GHD, in a randomized, parallel, double-blind, placebo-controlled trial for 1 yr, followed by an open phase with GH for 1 yr. All patients received GH therapy at the start of study, and trial medication (GH/placebo) was given in a similar dose. Patients randomized to continued GH treatment exhibited no significant changes in any parameters tested, but intra- and interindividual variations in insulin-like growth factor (IGF)-I levels could suggest compliance problems. Discontinuation of GH for 1 yr resulted in a decrease in serum IGF-I, from 422.0 +/- 56.8 to 147.8 +/- 33.4 microg/L, in the placebo group (P = 0.003). After discontinuation of GH for 1 yr, an increase in total body fat (TBF, kg), measured by dual-energy x-ray absorptiometry scan, was seen [placebo: 22.7 +/- 2.7 to 26.5 +/- 2.5 (P = 0.01); GH: 16.2 +/- 2.1 to 17.2 +/- 2.1 (not significant)]. Resumption of GH after placebo was followed by increments in serum IGF-I (microg/L) [from 147.8 +/- 33.4 to 452 +/- 76 (P = 0.001)] and IGF-binding protein 3, as well as in fasting glucose (mmol/L) [4.9 +/- 0.2 vs. 5.3 +/- 0.2 (P = 0.03)]. After resumption of GH lean body mass (kg) increased [52.4 +/- 4.9 vs. 60.7 +/- 5.6 (P = 0.006)]. Likewise, resumption of GH therapy increased thigh muscle volume and thigh muscle/fat ratio, as assessed by computed tomography [muscle volume (cm2/10 mm): 118.2 +/- 11.7 vs. 130.0 +/- 10.9 (P = 0.002); muscle/fat ratio: 1.33 +/- 0.24 vs. 1.69 +/- 0.36 (P = 0.02)]. In conclusion, discontinuation of GH treatment in GHD patients, during the transition from childhood to adulthood, induces significant and potentially unfavorable changes in IGF-I and body composition, both of which are reversed after resumption of GH treatment. By contrast, continuation of GH therapy results in unaltered IGF-I and body composition. We recommend continuation of GH therapy in these patients, to be undertaken in collaboration between pediatricians and adult endocrinologists.

Effects of 12 months of GH treatment on cortical and trabecular bone content of IGFs and OPG in adults with acquired GH deficiency: a double-blind, randomized, placebo-controlled study.

To investigate the effects of 12 months of GH treatment on cortical and trabecular bone content of IGFs, iliac crest bone biopsies were obtained from 25 patients with GH deficiency (9 women and 16 men; ages, 21-61 yr; mean, 46 yr) who were randomized to sc injections with GH (2 IU/m(2).d) or placebo for 12 months. Levels of IGF-I, IGF-II, IGF binding protein (IGFBP)-3, IGFBP-5, osteocalcin, OPG, RANKL, and total protein were determined in extracts obtained after EDTA and guanidine hydrochloride extraction. Calcium was determined after HCl hydrolysis. Comparing changes during GH or placebo treatment, significant increases were observed during GH substitution for cortical and trabecular bone content of IGF-I [mean difference vs. placebo (mean +/- SEM), 97 +/- 30 and 72 +/- 38%] and OPG (mean difference vs. placebo, 109 +/- 59 and 51 +/- 19%). Also, a significant decline was found for cortical osteocalcin (mean difference vs. placebo, -49 +/- 22%) during GH treatment. In conclusion, our results indicate that long-term GH treatment increases the accumulation of IGF-I and OPG in cortical and trabecular bone in patients with GH deficiency, and this may in turn lead to an increase in bone mass and improved skeletal biomechanical competence.

Effects of growth hormone (GH) administration on functional hepatic nitrogen clearance: studies in normal subjects and GH-deficient patients.

A decline in serum urea levels and urinary urea excretion is usually seen after GH administration in humans, indicating overall protein anabolism. Whether this reflects the diminished supply of alpha-amino acids for urea synthesis or a substrate-independent hepatic mechanism is unknown. To pursue this we measured the urea nitrogen synthesis rate (UNSR) and blood alanine levels before, during, and after a 4-h constant iv infusion of alanine (2 mmol/kg BW.h). UNSR was estimated hourly as urinary excretion corrected for gut hydrolysis and accumulation in total body water. The slope of the linear relationship between UNSR and circulating alanine levels represents the hepatic components of conversion of amino nitrogen and is denoted the functional hepatic nitrogen clearance (FHNC). Eight male volunteers were randomly investigated on three occasions: 1) after 12-h iv saline infusion, 2) after 12-h iv GH infusion (1 IU/h), and 3) after 2-day sc GH treatment (8 IU/day), followed by 12-h iv infusion of GH (1 IU/h). The UNSR (millimoles per h) during alanine infusion was significantly lower when the subjects were receiving GH therapy [maximum +/- SE, 133.0 +/- 6.9 (saline) vs. 96.7 +/- 11.1 (12-h GH; P < 0.01) vs. 106.5 +/- 7.5 (2-day GH; P < 0.05)]. FHNC (liters per h) was similar in all three studies [30.3 +/- 1.2 (saline) vs. 26.6 +/- 3.4 (12-h GH) vs. 27.0 +/- 2.6 (2-day GH)]. Six GH-deficient adult patients were randomly studied twice: 1) on regular daily (at 2000 h) sc GH therapy (3 IU/m2.day), and 2) after discontinuation of GH for 2 days. The UNSR during alanine infusion was likewise significantly lower when the patients were receiving GH therapy [147.7 +/- 11.7 mmol/h (no GH) vs. 123.9 +/- 9.1 mmol/h; P < 0.01]. FHNC (liters per h) values were similar in the two studies [29.2 +/- 3.8 (GH) vs. 27.5 +/- 4.5 (no GH)]. Our data confirm the anabolic action of GH and show that short term GH deprivation is associated with catabolism in terms of increased UNSR. The finding of unaltered FHNC suggests a GH-induced extrahepatic regulation of amino nitrogen conversion, rather than a substrate-independent hepatic mechanism.

Increased pulsatile, but not basal, growth hormone secretion rates and plasma insulin-like growth factor I levels during the periovulatory interval in normal women.

The secretion of GH changes during the menstrual cycle, exhibiting high levels during the periovulatory phase (PO). Previous studies have not investigated whether this difference in GH status is due to increased secretion or reduced clearance of pituitary GH and amplified pulsatile vs. basal GH secretion. It is also unclear whether the PO phase is accompanied by changes in circulating insulin-like growth factor I (IGF-I). In this study we investigated the 24-h GH release patterns in the early follicular (EF) vs. the periovulatory menstrual phase in the same individuals. Ten young (aged 24-34 yr) healthy women with regular menses were studied with deconvolution analysis of GH profiles obtained by blood sampling every 20 min for 24 h, followed by an arginine stimulation test. A high sensitivity immunofluorometric GH assay was used. All women were studied in both the EF and PO phases in random order. There were no differences in the basal GH secretion rate or GH half-life during the two phases. The number of GH secretory bursts identified during the 24-h sampling period was significantly increased during the PO (13.3 +/- 0.5) compared to the EF (10.3 +/- 0.6) phase (P = 0.002); conversely, the mean interburst interval was shorter in the PO (107 +/- 5 min) than in the EF (134 +/- 8 min) phase (P = 0.004). There was no difference in GH pulse mass (P = 0.13) or amplitude (P = 0.21) between the two phases. The pulsatile GH production rate (milligrams per L/24 h) was significantly elevated during the PO (61 +/- 6) compared to that during the EF (37 +/- 8; P = 0.004). Increased total GH pulse area was confirmed by Cluster analysis (P = 0.027). Furthermore, the 24-h mean serum GH concentration was significantly increased in the PO (1.4 +/- 0.1 mg/L) vs. that in the EF (0.9 +/- 0.1 mg/L; P = 0.002). There was a positive correlation between estradiol (E2) and GH secretory pulse amplitude, frequency, and mean 24-h serum GH concentration in the PO cycle phase, indicating E2 to be a major statistical determinant of GH secretion. Serum GH increased significantly after arginine infusion in both phases (P < 0.001), whereas there was no difference between the two cycle phases (P = 0.20). Serum IGF-I levels were increased during the PO phase (253 +/- 20 mg/L) compared to those during the EF phase (210 +/- 16 mg/L; P = 0.03), whereas serum IGF-binding protein-3, IGF-II, and GH-binding protein were similar during the two phases. This study unequivocally documents elevated GH levels during the PO phase of the menstrual cycle, mediated by increased GH production rate and burst frequency. The concomitant increase in serum IGF-I suggests a central stimulation of the GH-IGF-I axis, which may be mediated by endogenous E2 levels.

No effect of growth hormone on serum insulin-like growth factor binding protein-3 proteolysis.

Increased proteolysis of insulin-like growth factor binding protein (IGFBP)-3 is seen in several pathophysiological conditions and may represent an important mechanism for the regulation of insulin-like growth factor bioavailability. It has previously been suggested that proteolysis of IGFBP-3 is dependent on the GH status. To investigate this, IGFBP-3 proteolysis was measured in three groups of subjects: 1) GH-deficient patients before and after GH replacement (n = 14); 2) healthy subjects before and after 14 days of GH administration (n = 7); and 3) acromegalic patients before and after treatment with a long-acting SRIH analogue (octreotide; n = 14). In vivo IGFBP-3 proteolysis was investigated by Western immunoblotting. No difference was detected in pretreatment samples, and GH treatment in GH-deficient subjects or octreotide treatment in acromegalic subjects had no impact on in vivo proteolysis. In contrast, GH administration to healthy subjects caused a 21% increase in in vivo proteolysis (P = 0.0008). In vitro IGFBP-3 proteolysis was investigated by incubation of serum with 125I-rhIGFBP-3, followed by SDS-PAGE. In pretreatment samples, the percentage of proteolyzed 125I-rhIGFBP-3 was 13 +/- 1% (acromegalic subjects), 11 +/- 1% (healthy subjects), and 9 +/- 1% (GH-deficient subjects) (P < 0.009, GH-deficient vs. acromegalic subjects). Treatment had no effect on in vitro proteolysis. We conclude that GH status has no major impact on IGFBP-3 protease activity in serum.

Abdominal fat determines growth hormone-binding protein levels in healthy nonobese adults.

The circulating high affinity GH-binding protein (GHBP), which derives from the extracellular domain of the hepatic GH receptor, correlates inversely to GH levels and directly to body mass index (BMI) in healthy adults. As GH secretion and adiposity are also interrelated, we tested the hypothesis that body composition more than GH, determines GHBP levels in healthy adults. Forty-two healthy adults [21 females and 21 males; mean age, 39.4 yr range, 27-59 yr); mean BMI, 23.9 kg/m2 (range, 18.9-34.7 kg/m2)], underwent anthropometric measurements (BMI, W/H ratio, computed tomography scan, dual energy x-ray absortiometry (DEXA) scan, and bioimpedance) in addition to two GH stimulation tests (arginine and clonidine) and a 24-h GH profile. By simple linear regression, serum GHBP correlated positively to several indices of adiposity: intraabdominal fat (r = 0.537; P = 0.001), sc abdominal fat (r = 0.680; P < 0.001), BMI (r = 0.483; P = 0.001), W/H ratio (r = 0.452; P = 0.003), total body fat (DEXA scanning; r = 0.503; P = 0.002), and body fat (bioimpedance; r = 0.354; P = 0.023). Lean body mass estimated by DEXA scan was negatively associated with GHBP (r = 0.541; P < 0.001). GHBP was inversely proportional to arginine-stimulated GH release (r = -0.346; P = 0.027) and negatively associated with several measures of spontaneous GH release as estimated by deconvolution analysis (GH mass, GH production rate, and mean GH; r = -0.371; P = 0.017, r = -0.393; P = 0.011, and r = -0.343; P = 0.028, respectively)). With multiple linear regression analyses, indices of adiposity were significant determinants of GHBP levels, whereas GH status did not contribute independently to the prediction of GHBP. Neither insulin-like growth factor I nor fasting insulin levels correlated to GHBP levels. In conclusion, GHBP levels in normal adults seem to be determined by abdominal fat mass rather than GH secretion.

Metabolic effects and pharmacokinetics of a growth hormone pulse in healthy adults: relation to age, sex, and body composition.

The acute effects of a single GH pulse have previously been studied in young males. It is, however, likely that both the metabolic effects and the pharmacokinetics of GH may differ between age groups and sexes. We studied 36 healthy, clinically nonobese adults of both sexes, who were divided into a young group (mean age, 29.6 yr) and an older group (mean age, 51.0 yr). On 2 separate occasions, they received an i.v. bolus of either GH (200 micrograms) or saline followed by blood sampling for 5 h. Glucose turnover was estimated by infusion of [3-3H]glucose, and indirect calorimetry was performed before and 2 h after the bolus infusions. Body composition (computed tomography scan and dual energy x-ray absorptiometry) was performed at baseline. Baseline levels of serum insulin-like growth factor I (IGF-I) was lower in older subjects, whereas circulating IGF-binding protein-1 and lipid intermediates were lower in males than in females. The area under the GH curve was lower in older subjects (young, 3978 +/- 1532 micrograms/L.24 h; older, 1144 +/- 79; P = 0.001), whereas the elimination half-life did not differ with age (young, 18.1 +/- 0.9 min; older, 16.4 +/- 0.8; P = NS). The MCR and apparent distribution volume of GH were higher in older subjects [MCR: young, 0.11 +/- 0.02 min/L; older, 0.19 +/- 0.01; P = 0.001; apparent distribution volume: young, 2.5 +/- 0.4 L; older, 4.5 +/- 0.3; P < 0.001). Both MCR and Vd correlated inversely with age and positively with indexes of adiposity. GH significantly increased lipid intermediates, but the response was higher in young subjects and males. By contrast, the ability of GH to acutely suppress IGF-binding protein-1 was more pronounced in older subjects and females. Serum levels of insulin and IGF-I did not differ significantly between GH and saline treatment groups. GH decreased the respiratory exchange ratio and increased resting energy expenditure, with no age or gender differences. A gradual decline over time in plasma levels and rate of turnover of glucose was recorded after both GH and saline. The following conclusions were reached. 1) The MCR and Vd of GH increase with age and correlate positively with fat mass. 2) Older subjects are responsive to the acute lipolytic effects of GH, but the response is higher in young subjects and in males. 3) Adipose tissue may be actively involved in the distribution and clearance of GH. 4) Age, sex, and body composition interact with GH in a complex manner, involving clearance, distribution, and metabolic actions of the hormone.

Continuation of growth hormone (GH) therapy in GH-deficient patients during transition from childhood to adulthood: impact on insulin sensitivity and substrate metabolism.

The appropriate management of GH-deficient patients during transition from childhood to adulthood has not been reported in controlled trials, even though there is evidence to suggest that this phase is associated with specific problems in relation to GH sensitivity. An issue of particular interest is the impact of GH substitution on insulin sensitivity, which normally declines during puberty. We, therefore, evaluated insulin sensitivity (euglycemic glucose clamp) and substrate metabolism in 18 GH-deficient patients (6 females and 12 males; age, 20 +/- 1 yr; body mass index, 25 +/- 1 kg/m2) in a placebo-controlled, parallel study. Measurements were made at baseline, where all patients were on their regular GH replacement, after 12 months of either continued GH (0.018 +/- 0.001 mg/kg day) or placebo, and finally after 12 months of open phase GH therapy (0.016 mg/kg x day). Before study entry GH deficiency was reconfirmed by a stimulation test. During the double-blind phase, insulin sensitivity and fat mass tended to increase in the placebo group [deltaM-value (mg/kg x min), -0.7 +/- 1.1 (GH) vs. 1.3 +/- 0.8 (placebo), P = 0.18; deltaTBF (kg), 0.9 +/- 1.2 (GH) vs. 4.4 +/- 1.6 (placebo), P = 0.1]. Rates of lipid oxidation decreased [delta lipid oxidation (mg/kg x min), 0.02 +/- 0.14 (GH) vs. -0.32 +/- 0.13 (placebo), P < 0.05], whereas glucose oxidation increased in the placebo-treated group (P < 0.05). In the open phase, a decrease in insulin sensitivity was found in the former placebo group, although they lost body fat and increased fat-free mass [M-value (mg/kg x min), 5.1 +/- 0.7 (placebo) vs. 3.4 +/- 1.0 (open), P = 0.09]. In the group randomized to continued GH treatment almost all hormonal and metabolic parameters remained unchanged during the study. In conclusion, 1) discontinuation of GH therapy for 1 yr in adolescent patients induces fat accumulation without compromising insulin sensitivity; and 2) the beneficial effects of continued GH treatment on body composition in terms of decrease in fat mass and increase in fat-free mass does not fully balance the direct insulin antagonistic effects.

Growth hormone deficiency and hyperthermia during exercise: a controlled study of sixteen GH-deficient patients.

Sweat secretion is often disturbed in patients with GH secretory disorders. Hyperhidrosis is a classic feature of acromegaly, and it has recently been shown that GH-deficient patients exhibit decreased sweating capacity after pilocarpine stimulation of the skin. Thus, patients with GH-deficiency may be at risk for developing hyperthermia. To pursue this, we performed a controlled study on sweating and body temperature regulation during exercise in the heat in 16 GH-treated GH-deficient patients with normalized insulin-like growth factor-I and insulin-like growth factor/binding protein-3 serum levels [11 with multiple pituitary deficiency (MPD) and 5 with isolated GH deficiency] and in 10 healthy subjects as controls (CTs). Each subject exercised on a bicycle ergometer for 60 min at a workload corresponding to 45% of their individual maximal oxygen consumption (VO2max), in a room maintained at 35 C. GH serum concentrations increased significantly after approximately 10 min of exercise in the CTs (P < 0.001) but remained low in the patients. Body heat storage was significantly higher in the patients compared with the CTs [89 (SE +/- 10) watts (MPD) vs. 37 (SE +/- 8) watts (CTs), P < 0.001]. Consequently, the core temperatures of the patients increased significantly after exercise compared with those of the CTs [38.3 C (0.10 C) (MPD) and 38.1 C (0.06 C) (isolated GH deficiency) vs. 37.5 C (0.2 C) (CTs) (P < 0.004)]. Skin temperature increased significantly during exercise in the patients but remained unaltered in the CTs. Sweat secretion rates, as determined by the pilocarpine method, were significantly lower in the MPD patients [77 (SE +/- 10) mg/30 min] than in the CTs [115 (SE +/- 7) mg/30 min] (P < 0.005). Total body sweating was lower in the patients than in the CTs, although the difference did not reach statistical significance. Significantly reduced estimated evaporative heat loss was demonstrated in the patients compared with the CTs (P < 0.001). In conclusion, 1) decreased sweating, decreased sensitivity of the sweat gland, and impaired thermoregulation are part of the adult GH-deficiency syndrome, and 2) GH-deficient patients are at risk for developing hyperthermia during physical activity in hot environments.

Effects of 12 months of growth hormone (GH) treatment on calciotropic hormones, calcium homeostasis, and bone metabolism in adults with acquired GH deficiency: a double blind, randomized, placebo-controlled study.

The effects of GH substitution on skeletal mass, bone turnover, and calcium metabolism were investigated in 29 patients with GH deficiency who were randomized to sc injections with GH (2 IU/m2 day) or placebo for 12 months. During GH treatment, serum insulin-like growth factor I increased 263 +/- 98% (P < 0.001). Serum osteocalcin, bone a alkaline phosphatase, and procollagen type I C-terminal propeptide increased by 376 +/- 78% (P < 0.005), 128 +/- 17% (P < 0.005), and 100 +/- 17% (P < 0.005), respectively. Serum type I collagen telopeptide and urinary levels of pyridinoline, deoxypyridinoline, and hydroxyproline rose by 158 +/- 39% (P < 0.005), 170 +/- 48% (P < 0.005), 156 +/- 78% (P < 0.005), and 161 +/- 50% (P < 0.005), respectively. Serum ionized calcium rose by 1.7 +/- 0.6% (P < 0.05), whereas serum PTH decreased insignificantly. Vitamin D metabolites remained unaltered. Urinary calcium/creatinine increased and phosphate/creatinine decreased transiently, returning to baseline values at 9 months. When measured by dual energy x-ray absorptiometry, whole body bone mineral density (BMD) and (BMD) of the radius decreased 2.4 +/- 0.6% (P < 0.05) and 3.5 +/- 1.0% (P < 0.005), respectively, whereas no significant changes were observed in BMD of the femur or spine. Our results indicate that long term GH treatment activates bone remodeling in patients with GH deficiency. The observed slight decrease in BMD may be explained by expansion of the remodeling space and reduced mean age of bone tissue. IT remains unclear whether long term treatment with GH will lead to an increase in bone mass and improved skeletal biomechanical competence.

Impact of gender and androgen status on IGF-I levels in normal and GH-deficient adults.

OBJECTIVE: The regulation of IGF-I levels is complex and not only dependent on GH status, as the diagnostic sensitivity of serum IGF-I levels for GH deficiency (GHD) in adults is low. Other GH-related parameters have so far not proven to be of additional diagnostic value in GHD adults. In the present study we evaluated the impact of gender and androgen status on IGF-I levels and the diagnostic value of IGF-I and GH-related parameters in a population of adult hypopituitary patients and age- and gender-matched healthy subjects. DESIGN: A cross-sectional study. SUBJECTS: Fifty-nine GHD patients (40 males, mean age 39.3+/-1.7 (s.e.m.) years, and 19 females, mean age 41.9+/-2.6 years) and 69 healthy subjects (42 males, mean age 36. 7+/-1.5 years, and 27 females, mean age 38.9+/-2.1 years). RESULTS: IGF-I levels were low in the GHD patients (91+/-7 vs 173+/-7 microgram/l, P<0.001), and lower in female patients than in male (68+/-10 vs 100+/-8 microgram/l, P=0.03). In the control group there was no gender-related difference in IGF-I levels (males: 178+/-8, females: 164+/-12 microgram/l, P=0.23). IGF-II and IGF-binding protein-3 (IGFBP-3) were also decreased in GHD without any gender-related differences. GH-binding protein (GHBP) levels were increased in the patient group. The diagnostic sensitivity (%) of IGF-I, IGF-I/GHBP, IGF-I/IGFBP-3, and of the combination of IGF-I plus IGF-II (both low or one normal and one low), was higher in female patients than in male (IGF-I: 57.8 vs 22.0, P<0.0001; IGF-I/GHBP: 84.2 vs 48.8, P=0. 002; IGF-I/IGFBP-3: 36.8 vs 7.3 P=0.001; IGF-I+IGF-II: 77.8 vs 52.6, P=0.01). Testosterone levels were reduced in the female patients compared with female controls (0.5+/-0.3 vs 2.1+/-0.2nmol/l, P<0.001). Forward regression analyses revealed that IGFBP-3 was a significant predictor of IGF-I levels in both patients and healthy subjects. In a combined analysis of both patients and controls, sex hormone-binding globulin (SHBG) level was the main contributor as an explanatory variable. Gender and prolactin also predicted IGF-I in patients, whereas SHBG and estradiol were significant predictors only in the control group. CONCLUSION: (i) Levels of IGF-I, and of IGF-I/IGFBP-3 and IGF-I/GHBP ratios are lower in females compared with male adult GHD patients. (ii) IGF-I/GHBP has a high diagnostic sensitivity of adult GHD, in particular in women. (iii) We hypothesize that the gender difference in IGF-I levels among adult GHD patients are causally related to the very low androgen levels observed among females.

Serum free insulin-like growth factor-I in growth hormone-deficient adults before and after growth hormone replacement.

The objective of the present study was to compare fasting levels of free IGF-I in serum from patients with adult onset growth hormone deficiency (GHD) and from healthy volunteers, and to examine the effect of GH replacement therapy in GHD on serum free IGF-I. Free IGF-I was measured using separation of free IGF-I by ultrafiltration in serum samples from 42 healthy volunteers and 27 patients with GHD, in the latter before and after 1 year of treatment with GH (2 IU/m2) (n = 13) or placebo (n = 14). Free IGF-I was significantly decreased in patients with GHD (700 +/- 100 ng/l (mean +/- S.E.M.), range 55-2618 ng/l) compared with controls (1010 +/- 70 ng/l, range 231-2431 ng/l; P = 0.0016). Total IGF-I was 85 +/- 10 micrograms/l (GHD) and 160 +/- 10 micrograms/l (controls) (P < 0.0001). The ratio of free over total IGF-I was increased in GHD to 0.85 +/- 0.08% compared with 0.66 +/- 0.05% in controls (P = 0.04). In both GHD and controls, free IGF-I correlated significantly (P < 0.05) with total IGF-I (GHD r = 0.78; controls r = 0.42), IGFBP-1 (GHD r = -0.67; controls r = -0.46) and the molar ratio of total IGF-I over IGFBP-3 (GHD r = 0.58; controls r = 0.62). After 1 year of GH treatment, free IGF-I was increased to 2780 +/- 320 ng/l (P = 0.003) and total IGF-I was increased to 270 +/- 30 micrograms/l (P = 0.006) both of which values were greater than those in healthy volunteers. There were no changes in free or total IGF-I in the placebo-treated group. In conclusion, levels of free IGF-I are decreased in GHD, but measurements of free IGF-I in a single, fasting serum sample do not offer a better separation of patients with GHD from individuals with normal GH status than can be achieved by measurement of total IGF-I. One year of treatment with 2IU/m2 GH caused an increase of serum free IGF-I to supraphysiological levels.

Dose-, IGF-I- and sex-dependent changes in lipid profile and body composition during GH replacement therapy in adult onset GH deficiency.

OBJECTIVE: Patients with GH deficiency of adult onset (GHDA) exhibit dyslipidaemia and increased cardiovascular morbidity. GH replacement potently reduces body fat and serum lipids in GHDA. In recent years, lower GH doses have been introduced. The purpose of this analysis was to explore the response relationship between GH doses, lipids and body composition. DESIGN: Two consecutive, randomized 12-month GH replacement studies covering placebo and three different doses of GH (0.5, 1.0 and 1.7 IU/m(2) per day). Low and intermediate doses were IGF-I titrated. PATIENTS: Fifty-eight patients with severe GHDA, not previously treated with GH and stably substituted for other endocrine deficiencies, were included in the study. METHODS: Serum lipoproteins, serum IGF-I and body composition analysis by dual energy X-ray absorptiometry (DXA) were used. RESULTS: Fifty-seven percent of patients exhibited low density lipoprotein (LDL) cholesterol levels above 4.16 mmol/l, corresponding to the American Heart Association threshold of 160 mg/dl. GH treatment resulted in significant decreases in total and LDL cholesterol, with no significant change in high density lipoprotein cholesterol or triglycerides. The low dose induced no significant changes in lipid levels, whereas the medium dose reduced LDL cholesterol and the high dose decreased both LDL and total cholesterol. The effects depended significantly on the GH dose and the level of IGF-I obtained, but not on gender. GH replacement induced dose-dependent reductions in fat mass and sex-dependent increases in lean mass. CONCLUSIONS: GH given for 1 year at a dosage between 0.5 and 1.7 IU/m(2) per day reduced fat mass in a dose-dependent manner, increased lean body mass and lowered total and LDL cholesterol in patients with severe GHDA. Low dose GH treatment with normal IGF-I levels induced smaller changes compared with high dose therapy, and may need a longer treatment time.

Skin morphological changes in growth hormone deficiency and acromegaly.

OBJECTIVE: To evaluate the histomorphology of skin and its appendages, especially eccrine sweat glands, in patients with GH disorders, because reduced sweating ability in patients with growth hormone deficiency (GHD) is associated with increased risk of hyperthermia under stressed conditions. DESIGN AND METHODS: A skin biopsy was obtained from 17 patients with GHD treated with GH, five patients with untreated GHD, 10 patients with active acromegaly and 13 healthy controls. RESULTS: The sweat secretion rate (SSR) was significantly decreased in both the untreated (median 41 mg/30 min, range 9-79 mg/30 min) and the GH-treated (median 98 mg/30 min, range 28-147 mg/30 min) patients with GHD compared with that in controls (median 119 mg/30 min, range 90-189 mg/30 min; P=0.001 and 0.01 respectively). Epidermal thickness was significantly decreased in both untreated (median 39 microm, range 28-55 microm) and GH-treated patients with GHD (median 53 microm, range 37-100 microm), compared with that in controls (median 66 microm, range 40-111 microm; P<0.02). A statistically non-significant tendency towards thinner epidermis (median 59 microm, range 33-83 microm) was recorded in acromegalic patients (P=0.08) compared with controls. There was no significant difference in the area of the sebaceous glands in the biopsies between the three groups and the controls. The area of eccrine sweat gland glomeruli was significantly decreased in the untreated patients with GHD (median 16407 microm2, range 12758-43976 microm2) compared with that in controls (median 29446 microm2, range 13511-128661 microm2; P=0.03), but there was no significant difference between the GH-treated patients with GHD and controls. CONCLUSIONS: We conclude that GH, either directly or via IGF-I, may have both a structural and a functional effect on human skin and its appendages, and that patients with GHD have histomorphological changes in skin compared with controls. Importantly, these changes are not fully reversed despite long-term and adequate GH treatment in patients with childhood onset GHD.

Resting metabolic rate in healthy adults: relation to growth hormone status and leptin levels.

Studies in patients with acromegaly and growth hormone (GH) deficiency, and administration of GH in normal and obese subjects and in patients with GH deficiency, suggest that GH increases resting metabolic rate (RMR) independently of changes in body composition. To test whether endogenous GH status determines RMR, we studied 38 healthy adults (18 women and 18 men) in two age groups (young, 30+/-0 years (n=18); older, 51+/-1 years [n=18]) with indirect calorimetry, deconvolution analysis of 24-hour GH secretion, arginin stimulation test, insulin-like growth factor-I (IGF-I) measurement, lean and fat tissue distribution (computed tomography [CT] and dual-energy x-ray absorptiometry), assessment of physical fitness (maximal oxygen consumption [VO2max]), thyroid status, and serum leptin levels. RMR was higher in men compared with women, whereas RMR per lean body mass (LBM) (kcal x 24 h(-1) x kg(-1)) was higher in women (30.0+/-0.5 v 33.0 2/3 0.8; P=.003). GH secretion was higher in women and in young people. Total-body fat (TBF) was higher in women, whereas LBM and abdominal fat were higher in men. Older people had significantly more TBF and abdominal fat as compared with younger people. VO2max was higher in younger people. Leptin levels were higher in women and in older people. Thyroid status was narrowly within the normal range in all subjects. RMR was strongly correlated with LBM (r=.90, P < .001). RMR/LBM correlated strongly with TBF (r=.49, P < .01) and leptin (r=.56, P < .001), but not with GH status. By multiple regression analysis, sex and TBF were the strongest predictors of RMR/LBM. However, in the young subgroup, GH production rate was a positive determinant of RMR/LBM. In the male subgroup, leptin was a stronger predictor than TBF of RMR/LBM (P < .001). Neither age, physical fitness, nor thyroid status contributed independently to predict RMR/LBM. In conclusion, (1) LBM was the most important determinant of RMR; (2) RMR/LBM was higher in women and depended strongly on TBF; (3) GH status in healthy adults was only weakly associated with RMR; and (4) in men, serum leptin levels were a strong positive determinant of RMR.

Fuel metabolism in growth hormone-deficient adults.

Apart from being a stimulator of longitudinal growth, growth hormone (GH) regulates fuel metabolism in children and adults. A halfmark is mobilization of lipids, which involves an inhibition of lipoprotein lipase activity in adipose tissue and activation of the hormone sensitive lipase. Suppression of basal glucose oxidation and resistance to insulin are other important effects. This may cause concern during GH substitution in GH-deficient adults, some of whom may present with insulin resistance due to concomitant abdominal obesity. However, there are data to suggest that the GH-induced reduction in fat mass and increase in lean body mass may offset the insulin antagonistic actions of the hormone. The nitrogen-retaining effects of GH seem to involve a direct stimulation of protein synthesis in addition to secondary effects such as generation of insulin-like growth factor-I (IGF-I), hyperinsulinemia, and promotion of lipolysis. Thus, during periods of substrate affluence, GH acts in concert with insulin and IGF-I to promote protein anabolism. Postabsorptively, GH is primarily lipolytic and thereby indirectly protein-sparing. This effect becomes further accentuated with more prolonged fasting. In that sense, GH is unique by its preservation of protein during both feast and famine. These fuel metabolic effects add merit to the principle of GH substitution in hypopituitary adults.

Serum leptin is increased in growth hormone-deficient adults: relationship to body composition and effects of placebo-controlled growth hormone therapy for 1 year.

The gene product from the ob gene, leptin, has recently been characterized in humans. The circulating level of leptin is related to body mass index (BMI) and more closely to estimates of total body fat, whereas visceral fat has been reported to be of minor importance. However, it is unknown if leptin is directly regulated by hormones that influence substrate metabolism and body composition. We studied leptin in adult growth hormone (GH)-deficient (GHD) patients substituted with GH treatment for 12 months in a parallel double-blind, placebo-controlled study. Twenty-seven GHD adults aged 44.9 +/- 1.9 years underwent anthropometric measurements for determination of regional and total body fat (BMI, waist to hip ratio [WHR], computed tomographic [CT] scan, dual-energy x-ray absorptiometry [DEXA] scan, and bioimpedance analysis [BIA]) before and after 12 months of placebo-controlled GH substitution (2 IU/m2) in a parallel design. The same measurements were performed in 42 healthy adults aged 39.1 +/- 1.7 years. The logarithm of serum leptin levels correlated positively with abdominal subcutaneous fat and total body fat (BIA and DEXA) in untreated GHD patients and healthy subjects. Fasting insulin did not correlate with leptin levels in either of the groups. After 12 months of GH administration, the body composition of GHD patients was significantly changed with respect to a marked decrease in body fat. The relations of leptin to the estimates of body fat were maintained, and leptin was furthermore related to BMI and fasting insulin. In multiple linear regression analyses, additional estimates of visceral adiposity (intraabdominal fat and maximal anterior-posterior diameter determined by CT scan) were significant determinants of leptin in the healthy subjects. The increase in fasting insulin levels during GH substitution correlated negatively with the reduction in leptin levels (r = -.823, P = .003). At baseline, leptin levels were increased in the patients compared with controls in both sexes (women, 21.8 +/- 3.3 v 11.3 +/- 1.4 ng/mL, P = .002; men, 8.1 +/- 1.2 v 4.7 +/- 0.7 ng/mL, P = .008). Leptin levels were similar in GHD patients treated for 12 months compared with healthy controls for both women and men (women, 15.9 +/- 2.3 and 11.3 +/- 1.4 ng/mL, P = .163; men, 7.1 +/- 2.8 and 4.7 +/- 0.7 ng/mL, P = .759). In healthy adults and in GHD patients, leptin levels were significantly higher in women than in men (11.3 +/- 1.4 v 4.7 +/- 0.7 ng/mL, P < .001; 21.8 +/- 3.3 v 8.1 +/- 1.2 ng/mL, P < .001). Gender remained a significant determinant of leptin levels in several models of multiple linear regression analysis also including age, estradiol levels, insulin, and estimates of body fat. We conclude that leptin is increased but not differently regulated in GHD patients compared with normal subjects, and that leptin levels are closely related to estimates of body fat. This relationship is maintained during a decrease in body fat due to GH substitution.

Growth hormone treatment in adults: is there a true gender difference?

The importance of growth hormone (GH) deficiency in adults became evident at the end of the 1980s, when the first clinical studies on GH replacement therapy in adults were published. Since then, accumulated experience has shown a great individual variability in the response to GH replacement, including a potential difference in responsiveness between genders. The aim of this paper is to review the data regarding the effects of gender differences on GH pharmacokinetics, pharmacodynamics, and efficacy of replacement. In addition, we start with a short review of the possible role of GH in sexual development and sexual life.