Carbohydrate metabolism on high dose growth hormone therapy in children treated for leukaemia

The effect on carbohydrate metabolism of a high dose growth hormone (GH) regimen (1.2 U/kg per week) was assessed on 24 children who had previously been treated for leukaemia. Sixteen patients received high dose GH and eight patients received a conventional dose of GH (0.6 U/kg per week). Oral glucose tolerance tests (OGTT) were performed at baseline and after 3 months of treatment with GH. For the entire group between 0 and 3 months, there was a significant increase in mean (and standard deviation) fasting plasma glucose (0.3 +/- 0.6 mmol/L), fasting insulin level (11 +/- 26 mU/L), and 2 h insulin level (20 +/- 40 mU/L). One patient, who received a conventional dose of GH, developed substantial carbohydrate intolerance. For the entire group, there was no change in response to a carbohydrate load at 3 months as measured by the area under the plasma glucose or insulin curve. There was no significant difference between conventional and high dose groups at 3 months as assessed by these parameters. This study demonstrates that a higher dose of GH may be used in these children in an attempt to improve their final height, without increased risk of carbohydrate intolerance in the short term.     

Serum insulin-like growth factors I and II concentrations and growth hormone and insulin responses to arginine infusion in children with protein-energy malnutrition before and after nutritional rehabilitation

Serum insulin, growth hormone (GH), insulin-like growth factors (IGFs) I and II, cortisol, and albumin concentrations were measured in 15 children with kwashiorkor, 15 with marasmic-kwashiorkor, and 21 with marasmus, before and in the survivors, after nutritional rehabilitation, as well as in 10 underweight and eight normal Egyptian children. We also evaluated arginine-induced insulin and GH secretion. IGF-I concentrations were reduced in the three severely malnourished groups (0.07 +/- 0.03, 0.05 +/- 0.03, and 0.09 +/- 0.09 U/ml, respectively) but returned to normal after refeeding. IGF-II concentrations were low in the kwashiorkor (175 +/- 79 ng/ml), marasmic-kwashiorkor (111 +/- 57 ng/ml), and marasmic children (128 +/- 70.9 ng/ml) and returned to normal after nutritional rehabilitation. Basal GH levels were high in the three severely malnourished groups (21.9, 28.8, and 16.6 ng/ml, respectively) and returned to normal after refeeding (8.1, 6.5, and 6.0 ng/ml, respectively). GH responses to arginine were depressed in the three malnourished groups and improved significantly in marasmic-kwashiorkor and marasmic children after nutritional rehabilitation. Insulin responses to arginine were impaired in kwashiorkor, and marasmic-kwashiorkor children and improved significantly after refeeding. IGF-I levels correlated significantly with percent of expected weight (r = 0.52, p less than 0.001), percent of expected height (r = 0.42, p less than 0.001), and weight/(height)2 index (r = 0.34, p less than 0.01). IGF-I levels correlated positively with insulin levels (r = 0.421, p less than 0.001) and negatively with cortisol concentrations (r = -0.400, p less than 0.001).(ABSTRACT TRUNCATED AT 250 WORDS)     

Evaluation of growth hormone release in children using arginine and L-dopa in combination.

L-Dopa in a dose ranging from 125-500 mg and arginine monochloride in a dose of 0.5 gm/kg were given simultaneously to 56 children with short stature (height less than third percentile). Sixteen of these children were subsequently diagnosed as having growth hormone deficiency. The diagnosis of hyposomatotropism was based on clinical findings and on responses to the combination test and to arginine and L-dopa administered as separate tests. All of the remaining 40 children had a normal GH response of greater than 6 ng/ml to the combination test. However, in this group, nine children were identified who responded to the combination test but who failed to respond to arginine and L-dopa in individual tests. The data suggest that a positive response to arginine and L-dopa in combination in children, who do not respond to the usual provocative tests when administered individually, may fail to identify children with partial GH deficiency who would benefit from treatment. The integrated stimulated GH response in the 31 children in whom a normal GH response to all three tests occurred suggests that the effects of L-dopa and arginine are additive.     

The effects of galanin on growth hormone secretion in children of normal and short stature

We have evaluated the effect of galanin (Gal), a newly identified hypothalamic peptide, on growth hormone (GH) secretion in 10 children with normal stature (NS), nine with constitutional growth delay (CGD), and five with isolated GH deficiency (IGHD). Gal was infused intravenously at a rate of 8 or 15 micrograms/kg/h. All children also underwent an acute oral clonidine test (0.15 mg/m2). In CGD children the mean plasma GH peak after 8 micrograms/kg/h of Gal infusion (13.3 +/- 1.7 ng/mL; mean +/- SEM) was higher (p less than 0.02) than in NS children (8.5 +/- 0.8 ng/mL). When the dose of Gal was increased to 15 micrograms/kg/h the mean plasma GH peak in CGD children (18.5 +/- 3.5 ng/mL) was still higher than in the NS group (13.2 +/- 2.9 ng/mL), although not significantly so. In IGHD children the mean plasma GH peak elicited by 8 or 15 micrograms/kg/h of Gal (3.8 +/- 0.7 and 3.9 +/- 0.5 ng/mL, respectively) was lower than that obtained in either CGD (p less than 0.0002) or NS children (p less than 0.001). In NS children the mean plasma GH peak after acute clonidine administration (22.3 +/- 3.0 ng/mL) was higher than that observed after either dose of Gal used (p less than 0.001 and p less than 0.05 with 8 and 15 micrograms/kg/h, respectively). In CGD or IGHD children mean plasma GH peak after acute clonidine (14.8 +/- 2.6 and 4.1 +/- 1.2 ng/mL, respectively) was not significantly different from that observed after either dose of Gal.(ABSTRACT TRUNCATED AT 250 WORDS)     

Carbohydrate metabolism on high dose growth hormone therapy in children treated for leukaemia

Abstract The effect on carbohydrate metabolism of a high dose growth hormone (GH) regimen (1.2 U/kg per week) was assessed on 24 children who had previously been treated for leukaemia. Sixteen patients received high dose GH and eight patients received a conventional dose of GH (0.6 U/kg per week). Oral glucose tolerance tests (OGTT) were performed at baseline and after 3 months of treatment with GH. For the entire group between 0 and 3 months, there was a significant increase in mean (and standard deviation) fasting plasma glucose (0.3 ± 0.6 mmol/L), fasting insulin level (11 ± 26 mU/L), and 2 h insulin level (20 ± 40 mU/L). One patient, who received a conventional dose of GH, developed substantial carbohydrate intolerance. For the entire group, there was no change in response to a carbohydrate load at 3 months as measured by the area under the plasma glucose or insulin curve. There was no significant difference between conventional and high dose groups at 3 months as assessed by these parameters. This study demonstrates that a higher dose of GH may be used in these children in an attempt to improve their final height, without increased risk of carbohydrate intolerance in the short term.     

Should the duration of the insulin tolerance test be shortened to 90 minutes?

The insulin tolerance test (ITT) is a standard growth hormone (GH) provocative test to distinguish children with normal variant short stature (NVSS) from those with GH deficiency (GHD). We reviewed ITTs retrospectively in 52 short children using peak GH concentration of 7 ng/ ml as a cut-off level for GHD (peak GH <7 ng/ ml) and NVSS (peak GH > or =7 ng/ml). The average insulin dosage was 0.1 U/kg in children with NVSS and 0.08 U/kg in GHD. Hypoglycemia was achieved in all cases with an average plasma glucose nadir of 1.8 mmol/l (32 mg/dl) occurring between 15 and 45 min following administration. The average peak GH concentration was 12 ng/ml, occurring at 30-90 min. There were no serious adverse effects from the ITT. We conclude that the appropriate duration of ITT should be 90 minutes. The appropriate timing to obtain samples for plasma glucose level is at 0, 15, 30, 45, 60, and 90 min, and for GH concentrations at 0, 30, 45, 60, and 90 min. The shortened duration of ITT to 90 min will reduce the time spent and also the financial cost for unnecessary samples, while still ensuring a correct diagnosis for the patients.     

Growth hormone response to clonidine in obese children.

Basal and stimulated serum growth hormone (GH) levels after exercise, insulin induced hypoglycemia (IIH) and oral clonidine were evaluated in 20 (16 M, 4 F) normal statured obese (body mass index greater than or equal to 25 kg/M2) children. Basal serum GH levels (mean +/- SEM, 2.0 +/- 0.38 ng/ml) were not different from basal levels in non-obese children. The mean peak levels were 3.16 +/- 1.17 ng/ml, 2.15 +/- 0.36 ng/ml and 3.15 +/- 1.12 ng/ml (+/- SEM) after exercise, IIH and oral clonidine, respectively. The positive responses (peak level of serum GH greater than 7 ng/ml) were seen in 10% with exercise, in 10% with clonidine and in none with IIH test. These observations suggest that GH response to oral clonidine is subnormal in obese children.     

Clinical value of the gonadotropic hormone releasing hormone (GHRH) test in the diagnosis of growth deficiency

Many stimulation tests are available for the assessment of growth hormone release from the pituitary in clinical practice. Three of the most common tests are insulin-hypoglycaemia, arginine stimulation and spontaneous hGH nocturnal peaks and profiles. In this study we compared the Growth hormone releasing-hormone (GHRH)-test in a dose of 1 microgram/kg b.w. with these three other tests for evaluation of the somatotropic function of the pituitary. Each of these four tests was performed in 29 children with short stature due to growth failure of various etiologies and height-deficits (-SDS) of -3.0 +/- 0.5 SE. The peak plasma hGH levels of all patients after GHRH stimulation did not correlate with the respective peak values during insulin (r = 0.02) and arginine (r = 0.28) stimulation and with peak levels during the spontaneous nocturnal hGH profile (r = 0.18). The diagnostic value of the GHRH test alone is thus still questionable in establishing the diagnosis of a hypothalamic GHRH/GH defect, because some of these patients do not react to the first GHRH dose as one might expect, but only after a few days of repeated injections of GHRH (priming). The tolerance of intravenous injections of GHRH was excellent. The mean plasma GH response to GHRH was higher (p less than 0.05) in the group of children with constitutional short stature than in GH deficient patients, but there were overlaps in this group with normal volunteers and other groups of patients with growth failure.     

Effect of growth hormone-releasing factor on growth hormone release in children with radiation-induced growth hormone deficiency

Five male children who received cranial irradiation for extrahypothalamic intracranial neoplasms or leukemia and subsequently developed severe growth hormone (GH) deficiency were challenged with synthetic growth hormone-releasing factor (GRF-44), in an attempt to distinguish hypothalamic from pituitary dysfunction as a cause of their GH deficiency, and to assess the readily releasable GH reserve in the pituitary. In response to a pulse of GRF-44 (5 micrograms/kg intravenously), mean peak GH levels rose to values higher than those evoked by the pharmacologic agents L-dopa or arginine (6.4 +/- 1.3 ng/mL v 1.5 +/- 0.4 ng/mL, P less than .05). The peak GH value occurred at a mean of 26.0 minutes after administration of GRF-44. These responses were similar to those obtained in children with severe GH deficiency due to other etiologies (peak GH 6.3 +/- 1.7 ng/mL, mean 28.0 minutes). In addition, there was a trend toward an inverse relationship between peak GH response to GRF-44 and the postirradiation interval. Prolactin and somatomedin-C levels did not change significantly after the administration of a single dose of GRF-44. The results of this study support the hypothesis that cranial irradiation in children can lead to hypothalamic GRF deficiency secondary to radiation injury of hypothalamic GRF-secreting neurons. This study also lends support to the potential therapeutic usefulness of GRF-44 or an analog for GH deficiency secondary to cranial irradiation.     

Quantitation of urinary growth hormone in children with normal and abnormal growth

Urinary growth hormone (GH) excretion was quantitated in 12-h overnight urine collections obtained from 31 control children, ages 3 to 17 yr (group 1); 21 children, ages 5 to 19 yr with GH deficiency (group 2), and 30 subjects, ages 10 to 18 yr with idiopathic growth failure and normal GH stimulation tests (group 3). The output of urinary GH was measured in one acromegalic woman. The authenticity of urinary GH, 22 kDa, was confirmed by high-performance liquid chromatography. The elution pattern of urinary GH was identical to that of biosynthetic and pituitary-derived GH. The immunoreactive profiles characterized by monoclonal immunoradiometric GH assay and standard GH radioimmunoassay were identical. The quantity of GH (mean +/- SEM per kg body weight) in group 1 (0.27 +/- 0.02 ng/kg) was significantly greater than group 2 (0.08 +/- 0.02 ng/kg) or group 3 (0.17 +/- 0.02 ng/kg, p less than 0.01). Approximately 50% of the subjects in group 3 had urinary GH measurements indistinguishable from those observed in the GH-deficient population. Twelve hypopituitary patients (group 2) excreted significantly greater amounts of urinary GH in the first 12 h after GH administration compared to the baseline period (0.41 +/- 0.07 versus 0.12 +/- 0.02 ng/kg, p less than 0.01). Markedly elevated output of urinary GH (2.0 ng/kg) was documented in one acromegalic patient. The data suggest that measurements of urinary GH may be a useful, simple, and noninvasive screening test for identifying patients with GH deficiency or excess.     

儿童I型糖尿病青春发育前及青春期血清IGF-I和IGFBP-3水平监测

目的：研究儿童Ⅰ型糖尿病青春发育前及青春期血清胰岛素样生长因子I(IGF-I),胰岛素样生长因子结合蛋白3(IGFBP-3)水平变化,探讨生长激素 胰岛素样生长因子I(GH-IGF-I)轴与血糖控制的关系。方法：分别采用ELISA和免疫放射法测定63例Ⅰ型糖尿病患儿和47例正常对照血清IGF-I,IGFBP-3水平,用胶乳凝集法测定Ⅰ型糖尿病患儿的糖化血红蛋白(HbAIC)。结果：①青春发育前糖尿病患儿血IGF-I为(75.4±26.6) ng/ml,IGFBP-3为(2 756.1±763.8) ng/ml,与对照组［(103.9±46.5) ng/ml,(2 717.1±480.2 ng/ml)相比无统计学差异(P>0.05);但青春期糖尿病患儿血IGF-I和IGFBP-3［(178.2±65.9) ng/ml,(2 956.0±847.6) ng/ml］均低于对照组［(229.6±54.5) ng/ml,(3 393.2±748.9) ng/ml］］P<0.05。②新发病的I型糖尿病患儿胰岛素治疗后血IGF-I为(143.0±67.5) ng/ml,IGFBP-3为(2 740.0±449.8) ng/ml,较治疗前［(54.8±44.3) ng/ml, (2 233.8±336.2) ng/ml］明显升高(P<0.05)。③糖尿病组HbA IC与血IGF-I,IGFBP-3之间存在负相关关系(r=-0.32,-0.29,P<0.01或0.05)。④糖尿病组青春期HbAIC为(9.0±1.8)%,每日胰岛素用量为(0.86±0.30)U/kg,均高于青春期前［(7.8±1.8) %,(0.64±0.38) U/kg］(P<0.05)。结论：儿童Ⅰ型糖尿病血IGF-I,IGFBP-3水平较正常儿降低,尤其青春期患儿比正常同龄儿降低的程度更为显著,提示此类患者青春期存在GH IGF-I轴的严重紊乱,可能是导致这一时期血糖控制不良的重要原因。     

Growth hormone secretion in patients with constitutional delay of growth and pubertal development

Growth hormone levels were measured every 30 minutes during sleep over 9 hours in 20 prepubertal patients with constitutional delay of growth and puberty (CGD) and in 10 age-matched controls, all of whom had had normal GH responses to an orally administered dose of clonidine. We found no significant difference in the mean 9-hour overnight GH concentration between groups (4.5 +/- 1.8 ng/ml (mean +/- SD) in the CGD group, 4.4 +/- 2.8 ng/ml in the control group). Total GH output (258 +/- 99 U vs 222 +/- 135 U), total number of nocturnal GH pulses (3.6 +/- 0.8 vs 3.3 +/- 1.3), mean peak GH response during nocturnal sampling (13 +/- 1.2 ng/ml vs 13.2 +/- 1.3 ng/ml), and basal somatomedin C concentrations were not different in the children with growth delay and controls. We conclude that prepubertal patients with constitutional delay of growth and puberty secrete GH normally and do not seem to have any abnormality in GH regulation.     

Five years of growth hormone treatment in children with Prader-Willi syndrome. Swedish National Growth Hormone Advisory Group

The authors have followed 18 prepubertal children (3-12 years of age) with Prader-Willi syndrome during 5 years of growth hormone (GH) treatment. Initially, all the children participated in a randomized, controlled GH trial, conducted to assess the effects of GH treatment on growth, body composition and behaviour. GH was administered to group A (n = 9) at a dose of 0.1 IU/kg/day (0.033 mg/kg/day) for 2 years. Group B (n = 9) was untreated for the first year, but the children were given GH at a dose of 0.2 IU/kg/day (0.066 mg/kg/day) during the second year. Thereafter, all children stopped GH treatment for 6 months and were then restarted with GH at a dose of 0.1 IU/kg/day (0.033 mg/kg/day). During the first year of GH treatment, there was a dramatic increase in height SDS in both groups. The attained height percentile was maintained during the continued GH treatment. Five years after the start of GH treatment, mean height SDS is still above average for age. Four children have reached final height, all within 2 SD of target height. During the first year of GH treatment, body mass index (BMI) SDS decreased significantly from 3.0 to 1.5 SDS in group A and from 2.8 to 1.2 SDS in group B, but it increased again during the 6-month period without treatment. Following the restart of GH treatment, BMI SDS has stabilized at 1.7 SDS for group A and 2.5 SDS for group B. In 16 of 18 patients, fasting insulin, glucose and the A1c fraction of glycosylated haemoglobin remained within normal ranges during 5 years of GH treatment. Following a period of rapid weight gain, two children have developed non-insulin-dependent diabetes mellitus. Glucose homeostasis returned to normal when GH treatment was withdrawn. In conclusion, GH treatment has a proven favourable effect on growth and body composition in patients with Prader-Willi syndrome. Treatment should be individualized, and close surveillance of glucose homeostasis is needed, especially if the patient is severely obese.     

Administration of low-dose estrogen rapidly and directly stimulates growth hormone production

We tested the concept that estrogen directly stimulates growth hormone (GH) production by determining whether low-dose treatment with ethinyl estradiol increases the GH reserve, as assessed by levodopa administration, without inhibiting somatomedin-C (Sm-C) levels. Twenty-three prepubertal short normal children underwent levodopa tests before and after being treated with ethinyl estradiol. One bedtime dose of ethinyl estradiol (20 to 40 micrograms/sq m, n = 8) resulted in a significant increase in GH levels during levodopa testing, with no significant change in Sm-C levels (0.27 +/- 0.03 vs 0.36 +/- 0.1 units/mL). Two days of a comparable ethinyl estradiol dose (n = 12) raised the mean basal GH level (2.4 +/- 0.4 vs 9 +/- 3 ng/mL) and had a similar effect on peak GH response, without affecting the mean Sm-C level. Eighteen of the 23 patients responded (maximum GH level, greater than or equal to 7 ng/mL) to levodopa before estrogen; all 20 children who received ethinyl estradiol priming in a dose of 20 micrograms/sq m or more also responded. We conclude that low-dose estrogen therapy rapidly stimulates GH production without decreasing Sm-C plasma levels. These results support the concept that the estrogen effect is direct. This action may be important for the stimulation of growth by estrogen. This effect can be conveniently employed to enhance the specificity of the levodopa test for profound GH deficiency.     

Predictors of growth response to growth hormone in otherwise normal short children.

Sixty prepubertal short children (39 boys) with heights less than 2 SD for age and gender were treated daily for 1 year with recombinant human growth hormone (GH), either 0.1 IU/kg (group 0.1, n = 32) or 0.05 IU/kg (group 0.05, n = 28). Reserve of GH was determined by at least one GH provocative stimulus and 24-hour continuous blood withdrawal to determine the integrated concentration of GH (IC-GH). All participants had a GH response to provocative tests greater than 10 micrograms/L. The height velocity (mean +/- SD) of the group as a whole increased from 4.46 +/- 1.02 to 7.59 +/- 1.65 cm/yr (p less than 0.001). The growth velocity of group 0.1 was significantly greater than that of group 0.05 (8.1 +/- 1.5 vs 7.0 +/- 1.65 cm/yr; p less than 0.01). Bone age did not advance more than 1 year during the treatment period. Growth velocity after 1 year of GH therapy was inversely correlated with the IC-GH in both groups, as was the pretreatment height velocity. We found no correlation of growth velocity during GH therapy with other measures such as parental heights, bone age/chronologic age ratio, maximal GH response to provocative tests, chronologic age, or pretreatment insulin-like growth factor I levels. We conclude that the best predictors for the 1-year growth outcome of short children with a normal GH response to provocative tests are the pretreatment growth velocity and the IC-GH. The short-term benefit from GH therapy in children with a normal growth velocity and a normal IC-GH is poor, whereas marked growth acceleration is noted in children with a low growth velocity and a low 24-hour IC-GH.     

Oral clonidine: an effective growth hormone provocative test

Twenty normal statured healthy children (8 M; 12 F) aged 9-16 years were subjected to growth hormone (GH) provocative tests. The mean basal GH level was 2.0 +/- 0.42 ng/ml (+/- SEM). The mean peak levels of GH were 11.9 +/- 2.19 ng/ml (+/- SEM) after exercise, 9.82 +/- 2.81 ng/ml (+/- SEM) after insulin and 15.2 +/- 2.54 ng/ml (+/- SEM) after oral clonidine. A significant rise (peak level greater than 7 ng/ml) of serum GH was found in 70, 80 and 85% of children after exercise, insulin and oral clonidine tests, respectively. The observation in the present study indicates that oral clonidine test, a safer, easier and more economical test than insulin hypoglycemia, is equally potent and can be done in out patients.     

Low dose (0.05 units/kg/h) is comparable with standard dose (0.1 units/kg/h) intravenous insulin infusion for the initial treatment of diabetic ketoacidosis in children with type 1 diabetes—an observational study

Puttha R, Cooke D, Subbarayan A, Odeka E, Ariyawansa I, Bone M, Doughty I, Patel L, Amin R. Low dose (0.05 units/kg/h) is comparable with standard dose (0.1 units/kg/h) intravenous insulin infusion for the initial treatment of diabetic ketoacidosis in children with type 1 diabetes—an observational study
Objective: To compare low dose (0.05 units/kg/h) with standard dose (0.1 units/kg/h) intravenous insulin infusion for the treatment of diabetic ketoacidosis (DKA) in children with type 1 diabetes.
Study design: Data from five paediatric centres were compared in children who received 0.05 (41 episodes) or 0.1 units/kg/h (52 episodes).
Results: In the low vs. standard dose group, at 6 h following admission, the fall in blood glucose levels [11.3 (95% confidence interval 8.6 to 13.9) vs. 11.8 (8.4 to 15.2) mmol/L, p = 0.86] and rise in pH [0.13 (0.09 to 0.18) vs. 0.11 (0.07 to 0.15), p = 0.78] were similar. These changes were comparable between doses in relation to: severity of initial acidosis, children newly diagnosed with diabetes or aged less than 5 years. After adjustment for other clinical and biochemical covariates, insulin dose was unrelated to the change in pH and blood glucose levels at 6 h following admission. Comparisons of safety data, particularly in relation to abnormal Glasgow Coma Score, were inconclusive.
Conclusion: In this observational study, low dose was as effective as standard dose intravenous insulin infusion in the initial treatment (less than 6 h) of DKA in children with type 1 diabetes. A randomised controlled trial is required to show true equivalence between doses and to evaluate potential safety benefits.     

Growth hormone treatment of short children born small-for-gestational-age: the Nordic Multicentre Trial

The aims of this study were to evaluate the efficacy and safety of different doses of growth hormone (GH) treatment in prepubertal short children born small-for-gestational-age (SGA). Forty-eight children born SGA from Sweden, Finland, Denmark and Norway were randomly allocated to three groups: a control group of 12 children received no treatment for 2 y, one group was treated with GH at 0.1 IU/kg/d (n = 16), and one group was treated with GH at 0.2 IU/kg/d (n = 20). In total 42 children completed 2 y of follow-up, and 24 children from the treated groups completed 3 y of treatment. Their mean (SD) age at the start of the study was 4.69 (1.61) y and their mean (SD) height was -3.16 (0.70) standard deviation scores (SDS). The children remained prepubertal during the course of the study. No catch-up growth was observed in the untreated group, but a clear dose-dependent growth response was found in the treated children. After the third year of treatment, the group receiving the higher dose of GH, achieved their target height. The major determinants of the growth response were the dose of GH used, the age at the start of treatment (the younger the child, the better the growth response) and the family-corrected individual height deficit (the higher the deficit, the better the growth response). Concentration of insulin-like growth factor-I (IGF-I) and IGF-binding protein-3 increased during treatment. An increase in insulin levels was found without negative effects on fasting glucose levels or glycosylated haemoglobin levels. GH treatment was well tolerated. In conclusion, short prepubertal children born SGA show a dose-dependent growth response to GH therapy, and their target height SDS can be achieved within 3 y of treatment given GH at 0.2 IU/kg/d. However, the long-term benefit of different regimens of GH treatment in children born SGA remains to be established.     

Basal and stimulated levels of growth hormone, insulin-like growth factor-I (IGF-I), IGF-I binding and IGF-binding proteins in beta-thalassemia major

A significant percentage of children with beta-thalassemia major shows retardation in longitudinal growth as they progress towards puberty due to skeletal dysplasia, endocrine gland hypofunction or trace element deficiencies. The aim of this study was to evaluate GH/IGF-I secretion and action in prepubertal patients with beta-thalas-semia major. Eight prepubertal patients with short stature (group A) and seven prepubertal patients with normal stature (group B) were studied. Basal and stimulated (after administration of the hexapeptide Hexarelin) GH levels were measured with IRMA (Nichols); IGF-I and IGFBP-3 levels were measured with RIA (Nichols). IGF-I binding proteins (IGFBPs) were analyzed qualitatively with Western ligand blot. IGF-I binding to B-lymphocytes of the patients was also measured with competitive binding studies using human recombinant IGF-I and 125I-IGF-I (Amersham). Basal GH levels did not differ statistically between the groups. Peak GH levels after Hexarelin stimulation test were higher in group A (A: 27.9 +/- 15.6 ng/ml vs B: 9.1 +/- 4.7 ng/ml) (Wilcoxon test, p < 0.05). IGF-I levels in the two groups were low-normal and comparable (A: 168.0 +/- 81.6 ng/ml vs B: 126.6 +/- 25.5 ng/ml). IGFBP-3 levels were low in both groups (A: 1.21 +/- 0.27 microg/ml vs B: 1.08 +/- 0.20 microg/ml). Western ligand blot did not reveal any discernible difference in IGFBPs. However, IGF-I binding on B-lymphocytes was at least 20% lower in group A compared to group B (t-test, p < 0.01). IGF-I binding inversely correlated with peak GH levels (r = -0.54, p < 0.05). Patients in group A were older and chronological age correlated with IGF-I levels (r = 0.53, p < 0.05) whereas it inversely correlated with IGF-I binding (r = -0.63, p < 0.05). Moreover, patients in group A had higher ferritin levels. No correlation was found between ferritin levels, desferrioxamine dose/compliance or liver enzyme levels and the parameters of the GH axis studied. However, desferrioxamine dose x years correlated with IGFBP-3 (r = 0.56, p < 0.05) and correlated inversely with IGF-I binding (r = -0.74, p < 0.01). In conclusion, we have shown adequate GH secretion, higher secretive capacity after the administration of Hexarelin and lower IGF-I binding in prepubertal beta-thalassemic patients with short stature. Whatever the cause, reduced IGF-I action has to be considered when treating beta-thalassemic patients with short stature.     

Acipimox, a nicotinic acid analog, stimulates growth hormone secretion in short healthy prepubertal children

Recent studies in adult volunteers have demonstrated that the free fatty acid reduction induced by acipimox, a nicotinic acid analog, stimulated GH secretion per se and enhanced in an additive manner the GH secretion elicited by such different stimuli as pyridostigmine, GHRH and GHRP-6. In order to evaluate whether acipimox administration stimulates GH secretion in prepubertal children, we administered a single oral dose of acipimox (100 mg for children weighing <30 kg and 200 mg for those >30 kg) to 14 healthy prepubertal children with a mean age of 8.2 +/- 1.9 years, a mean bone age of 6.2 +/- 3.0 years, growing along the 5-10th percentiles, and with normal thyroid function and IGF-I levels. Acipimox administration elicited a sustained increase in GH from a mean baseline level of 0.6 +/- 0.4 to 6.7 +/- 2.4 microg/l at the end of the test (p<0.05), with a mean GH peak of 10.5 +/- 3.5 microg/l. GH release was delayed so that peak GH levels were achieved 180 minutes after acipimox administration. In order to determine whether acipimox was capable of enhancing the GH secretion elicited by levodopa (L-Dopa), we administered either oral L-Dopa (250 mg for children weighing <30 kg and 500 mg for those >30 kg) or oral acipimox plus L-Dopa to the same children on different days. GH concentrations increased in a similar fashion following either of these tests (from a baseline level of 1.2 +/- 0.4 and 0.7 +/- 0.4 microg/l to 8.4 +/- 2.7 and 9.3 +/- 2.9 microg/l at the end of the test (p<0.001), with peak GH concentrations of 13.1 +/- 4.1 and 11.8 +/- 3.3 microg/l after L-Dopa or acipimox plus L-Dopa, respectively). Although the peak GH concentrations obtained after the combined administration of acipimox plus L-Dopa were similar to those obtained after either acipimox or L-Dopa administration, a larger number of our patients reached a GH cut-off point of >7 microg/l following combined therapy than with either stimulus alone (13/14 patients with combined therapy and 10/14 with acipimox alone). No side effects other than mild facial flushing were noted after acipimox administration. These results indicate that: 1) following the administration of a single oral dose of acipimox, significant GH secretion was elicited in healthy short prepubertal children; 2) the combined administration of acipimox plus L-Dopa did not, however, enhance the GH secretion of this group of children; 3) acipimox was well tolerated with minimal side effects; and 4) further studies in both GH sufficient and GH deficient children are necessary to evaluate acipimox's usefulness in assessing GH reserve.