Comparison of spontaneous growth hormone secretion during daytime and sleep in children with short stature

The authors compared diurnal growth hormone (GH) secretion with GH secretion during sleep in 24 children with delayed growth. In group I (children with normal response to provocative tests), the level of daytime secretion was lower than that of nocturnal secretion. In 3 of 9 cases, daytime secretion was abnormal, whereas nocturnal secretion was normal. In 2 cases, both diurnal and nocturnal secretion were abnormal, but response to provocative stimuli was normal. In group II (children with a false partial GH deficiency, i.e. with inadequate response to provocative tests, GH peak less than 11 ng/ml and normal nocturnal secretion), the results were comparable with those of group I, with extremely low diurnal secretion in 6 of 9 cases. In group III (children presenting true partial GH deficiency, i.e. GH less than 11 ng/ml in response to provocative tests together with abnormal nocturnal secretion), both diurnal and nocturnal GH secretion were insufficient, with nonexistent diurnal secretion in 5 of 6 cases. Diurnal secretion does not seem to be a reliable indicator of 24-hour spontaneous secretion.     

Partial growth hormone deficiency (GHD) in children has more similarities to idiopathic short stature than to severe GHD

INTRODUCTION: Assessment of growth hormone (GH) secretion is based on stimulation tests. Low GH peaks in stimulation tests, together with decreased insulin-like growth factor-I (IGF-I) secretion, confirm a diagnosis of GH deficiency (GHD). However, limitations in interpreting the test results and discrepancies between GH and IGF-I secretion in particular patients have both been reported. GH therapy should improve the prognosis of adult height (PAH). The aim of the study was to compare the deficit of height at diagnosis, IGF-I secretion and PAH in children with either decreased (in varying degrees of severity) or normal GH secretion in stimulation tests. MATERIAL AND METHODS: The analysis comprised 540 short children (373 boys, 167 girls), aged 11.7 +/- 3.2 years. In all the patients two GH stimulation tests were performed, IGF-I serum concentration was measured, bone age was assessed and PAH was calculated. According to the GH peak in the two stimulation tests, the patients were classified into the following groups: severe GHD (sGHD)--GH peak < 5 ng/mL (n = 44), partial GHD (pGHD)--GH peak 5-10 ng/mL (n = 190), idiopathic short stature (ISS)--GH peak at least 10 ng/mL (n = 306). RESULTS: A significantly greater deficit of height, lower IGF-I secretion and worse PAH were observed in sGHD than in both remaining groups, while all the differences between pGHD and ISS in the parameters analysed were insignificant. CONCLUSION: The results obtained indicate the necessity of applying another methods of qualifying short children for GH therapy other than GH stimulation tests with a cut-off value at a level of 10 ng/mL.     

Subcutaneous treatment with growth hormone-releasing hormone for short stature

In the present study we report the effects of therapy with growth hormone-releasing factor (1-29)NH2 (GRF) on growth rate, plasma levels of insulin growth factor I (IGF-I) and growth hormone (GH) secretion in 11 children who were selected solely on the basis of their short stature and normal GH secretion on standard provocative tests. All children received GRF for 6 months (5 micrograms/kg body weight subcutaneously) each evening. The 24-hour GH secretory profile was studied before and after 6 months of treatment. Simultaneously, GH secretory responses to single intravenous bolus GRF (1.5 micrograms/kg body weight) were also studied before, during, and 6 months off therapy with GRF(1-29)NH2. Plasma levels of IGF-I were measured before, during (1, 2 and 6 months), and after 6 months off therapy with GRF. Statural growth was measured at 3-month intervals. The peak plasma GH level in response to GRF was 56.04 +/- (SD) 24.46 ng/ml before treatment, and similar results were found after therapy. The 24-hour GH secretory profile did not show differences before, during, and after treatment. Comparably, no differences were found in GH pulse frequency, pulse amplitude, pulse height, pulse increment, pulse area and total area before, and 6 months off therapy with GRF. The increments in serum IGF-I achieved were not significantly different at all intervals studied. All patients increased growth velocities (mean +/- SD, cm/year) in response to GRF therapy. Our results demonstrate that GRF administration was effective in accelerating growth velocity in 11 children without GH deficiency.     

Pulsatility of growth hormone secretion and its relation to growth.

84 short children were submitted to nocturnal spontaneous growth hormone (GH) secretion tests and to provocative insulin-arginine tests. Discrepancies between the GH peak under the provocative test (I-AP) and nocturnal GH maximal peak (PA) and mean concentration (MC) were frequently observed, despite significant statistical correlation between I-AP and PA (r = 0.47; p < 0.02) and between I-AP and MC (r = 0.42; p < 0.02). Night profiles were evaluated by time analysis: 31 fitted a theoretical model, consisting of a cosine function of time (modelizable profiles). Spectral analysis, from Fourier transformation, indicated predominant periods after cluster analysis. The major predominant period in modelizable (n = 9) and in nonmodelizable (n = 28) profiles was close to 180 min and a secondary period was on average 122 min in modelizable (n = 20) and 105 min in nonmodelizable (n = 23) profiles. Two modelizable and two nonmodelizable profiles escaped this classification. The general, auxological and GH secretory status did not differ significantly between patients with modelizable and nonmodelizable profils. Growth velocity correlated with GH mean concentration (r = 0.36; p < 0.001), but not with plasma insulin-like growth factor-I levels nor with any of the pulsatility indices: number of peaks, main period, and pulse height index = mean GH peak/mean GH concentration. The relevance of GH pulsatility to growth is, therefore, unclear in humans.     

Crosstalk between GH/IGF-I axis and steroid hormones (progesterone, 17beta-estradiol) in canine mammary tumours

Growth hormone (GH), insulin-like growth factor I (IGF-I), progesterone (P4) and 17beta-estradiol (17-E2) concentrations have been studied in 84 mammary tumours (44 dysplasias and benign tumours and 40 malignant neoplasias) from 33 female dogs. Thirteen normal mammary glands from 80 healthy female dogs were also analysed as controls. GH concentrations were determined in mammary homogenates by radio-immunoassay. IGF-I, P4 and 17-E2 tissue levels were determined by enzyme-immunoassay (EIA) techniques. The potential correlations between GH/IGF-I concentrations and P4 and 17-E2 mammary tissue levels were investigated. Tissue GH (p<0.01) and IGF-I concentrations (p<0.01) were significantly higher in malignant tumours than in benign neoplasms. Likewise, malignant tumours were the mammary lesions that displayed the highest P4 and 17-E2 tissue levels. Strong correlations between GH/IGF-I (n=84; r=0.436; p<0.001), P4/GH (n=84; r=0.562; p<0.001) and 17-E2/IGF-I (n=84; r=0.638; p<0.001) were observed in tumoral tissue homogenates. Our study provides evidence that P4 might increase autocrine GH production which might directly stimulate local or systemic IGF-I secretion. Additionally, the IGF-I effect might be influenced by local levels of 17-E2. These results suggest that all these hormones and factors might act as local growth factors stimulating the development and/or maintenance of canine mammary tumours in an autocrine/paracrine manner.     

Spontaneous growth hormone secretion and plasma somatomedin-C in children of short stature

We studied 17 short prepubertal children, aged 7.5 to 17.0 years (mean +/- SD: 11.7 +/- 2.4) more than 2.0 SD below the mean height for their age and of delayed bone age (M +/- SD: 8.1 +/- 2.3), to clarify their physiological GH secretory status. The mean concentration of GH (MCGH) was calculated and was compared with the subjects' GH responses to insulin and arginine tolerance tests (IATT) and plasma somatomedin-C (SM-C). The mean 24-h MCGH value was 3.2 +/- 1.3 ng/ml (range 1.6-5.5). The mean peak GH response to the IATT was 13.0 +/- 7.5 ng/ml (range 2.4-33.9). In addition to the two patients with abnormally low GH responses to the IATT, seven with normal responses showed low 24-h MCGH values, a small number of GH pulses and low mean GH amplitude. The mean plasma SM-C in all patients was 0.60 +/- 0.20 U/ml. This was significantly lower than that of age-matched children of normal height (p less than 0.001). The 24-h MCGH was significantly correlated with plasma SM-C levels (r = 0.51, p less than 0.05) and with that of the first three hours of sleep at night (r = 0.84, p less than 0.01). These results indicate that: 1) some short children with normal GH response to pharmacological tests secrete a low amount of GH physiologically and 2) blood sampling during the first three hours of sleep as well as 24-hour sampling is suitable in evaluating the physiological secretion of GH.     

Insulin-like growth factors as diagnostic tools in growth hormone deficiency during childhood and adolescence: the KIGS experience

Growth hormone (GH) deficiency in children covers a spectrum of disorders involving an impairment in GH secretion and a clinical syndrome characterized by permanent stunting of growth. Ascertaining impairments in GH secretion directly is complex, especially if GH deficiency (GHD) is isolated and not caused by congenital or acquired pituitary defects or genetic abnormalities. It has been established that the concentrations of GH-dependent peptides, such as insulin-like growth factor I (IGF-I) and IGF-binding protein 3 (IGFBP-3), are low in patients with GHD. Their levels are, however, also influenced by a multitude of factors, such as age, gender, height, liver function, nutritional status and other hormones. In addition, the type of complex formed, e.g. either binary or ternary, may influence the measurements of IGFs and their binding proteins. Therefore, levels of IGF-I and IGFBP-3 are generally lower in short children compared with age-matched norms. The reported diagnostic value of sub-normal basal levels of IGF-I and IGFBP-3 is, in terms of sensitivity and specificity, approximately 70%. Thus, definite proof of GHD can only be achieved by means of GH measurements. As the diagnosis of GHD is somewhat unlikely if IGF testing shows normal values, it is clearly advantageous to schedule these tests as part of the initial diagnostic work-up in short children, as their implementation is not only practical but also inexpensive. The Pfizer International Growth Database (KIGS) analysis of IGF-I (n = 2,750) and IGFBP-3 (n = 1,300) levels in children with idiopathic GHD shows that these two parameters are now firmly embedded in diagnostic strategies around the world.     

Growth hormone activates renin-aldosterone system in children with idiopathic short stature and in a pseudohypoaldosteronism patient with a mutation in epithelial sodium channel alpha subunit

Growth hormone (GH) treatment causes salt and water retention, and this effect has been suggested to be mediated by activation of epithelial sodium channel (ENaC). Multi-system pseudohypoaldosteronism (PHA) is a salt wasting disease resulting from mutations in ENaC subunit genes. We examined effects of GH therapy for 12-21 months on the renin-angiotensin-aldosterone system (RAAS) in 12 children with idiopathic short stature (ISS) and a PHA patient with defective ENaC function and concomitant GH deficiency. On GH therapy (0.7 U/kg/week), plasma renin activity (PRA), serum aldosterone and insulin-like growth factor-I (IGF-I) levels were periodically determined every 1-3 months in all children. The PHA patient was studied for 6 yr during which time serum, urine, and sweat electrolytes and secretion rate were also examined before, on and off GH therapy. In the PHA patient, mean plasma aldosterone concentration, 7.7 nmol/l (278 ng/dl) before therapy (n=9) rose to 73 nmol/l (2650 ng/dl) 10 months after GH. PRA and IGF-I increased similarly, reaching a plateau between 8 and 12 months. Off GH, there was a decrease to pretreatment levels in 30 months. Aldosterone and PRA strongly correlated with IGF-I (r=0.66 and 0.67). GH therapy also improved the growth rate, and increased both sweat secretion rate and Na(+)/K(+) ratio. In children with ISS, aldosterone and IGF-I peaked 6-12 months after GH. Off GH their levels normalized in 3 months. These findings indicate that long-term GH activates the RAAS in both children with ISS and a PHA patient, and that this effect does not depend on a fully functional ENaC.     

Growth hormone release in children after cranial irradiation

Growth retardation due to growth hormone (GH) deficiency is common in children after radiotherapy to the brain. Different methods for assessment of GH secretion were compared in 19 children who had received radiotherapy to the brain as part of treatment for a tumor of the brain, eye or epipharynx. GH was measured over a 24-hour period (72 sampling periods of 20 min each), as well as after administration of growth hormone-releasing hormone (GHRH) and arginine-insulin (AITT) tests. We found the 24-hour GH profile to be disturbed in all children; there was a low overall secretion with few peaks of low amplitude but a diurnal rhythm still discernable. In 16 children a prompt rise in GHRH after GHRH1-40 was seen indicating hypothalamic damage. The GH response after GHRH was not found to be correlated to the spontaneous secretion over 24 h. The results of the AITT showed discrepancies to the 24-hour GH profile in individual cases making this test unreliable in spite of a good overall correlation between the tests. Therefore, we suggest measurement of spontaneous secretion when GH-secretory capability is to be evaluated after cranial irradiation for a brain tumor.     

Insights into a role of GH secretagogues in reversing the age-related decline in the GH/IGF-I axis

Growth hormone (GH) secretion and serum insulin-like growth factor-I (IGF-I) decline with aging. This study addresses the role played by the hypothalamic regulators in the aging GH decline and investigates the mechanisms through which growth hormone secretagogues (GHS) activate GH secretion in the aging rats. Two groups of male Wistar rats were studied: young-adult (3 mo) and old (24 mo). Hypothalamic growth hormone-releasing hormone (GHRH) mRNA and immunoreactive (IR) GHRH dramatically decreased (P < 0.01 and P < 0.001) in the old rats, as did median eminence IR-GHRH. Decreases of hypothalamic IR-somatostatin (SS; P < 0.001) and SS mRNA (P < 0.01), and median eminence IR-SS were found in old rats as were GHS receptor and IGF-I mRNA (P < 0.01 and P < 0.05). Hypothalamic IGF-I receptor mRNA and protein were unmodified. Both young and old pituitary cells, cultured alone or cocultured with fetal hypothalamic cells, responded to ghrelin. Only in the presence of fetal hypothalamic cells did ghrelin elevate the age-related decrease of GH secretion to within normal adult range. In old rats, growth hormone-releasing peptide-6 returned the levels of GH and IGF-I secretion and liver IGF-I mRNA, and partially restored the lower pituitary IR-GH and GH mRNA levels to those of young untreated rats. These results suggest that the aging GH decline may result from decreased GHRH function rather than from increased SS action. The reduction of hypothalamic GHS-R gene expression might impair the action of ghrelin on GH release. The role of IGF-I is not altered. The aging GH/IGF-I axis decline could be rejuvenated by GHS treatment.     

Twenty-four hour plasma GH, FSH and LH profiles in patients with Turner's syndrome

We studied the plasma GH profiles in 6 patients with Turner's syndrome and 6 normal girls of short stature by sampling every 20 min for 24 hours. We observed episodic secretion of GH in these subjects. The mean plasma 24 h GH level in patients with Turner's syndrome was 3.6 +/- 1.4 (SD) ng/ml which was significantly lower than that of normal short girls (7.1 +/- 2.2 ng/ml, p less than 0.01). The GH secretion during both nighttime and daytime was decreased in the patients with Turner's syndrome, however the number of pulses did not differ significantly. There were no correlations between the mean plasma 24 h GH level on one hand and peak GH level obtained after GH provocative test and plasma somatomedin C on the other. Plasma FSH and LH levels were also measured in 4 patients with Turner's syndrome. Both levels were elevated and there observed no clear pulsatile secretion of FSH, but, some pulsatile secretion of LH was observed in two patients. These data indicate that patients with Turner's syndrome have decreased endogenous GH secretion, even though they show normal GH responses to GH provocative tests.     

Growth hormone secretion during sleep. I. Comparison with GH responses to conventional pharmacologic stimuli in pubertal and early pubertal short subjects. Effects of treatment with human GH in patients with discrepant measurements of GH secretion

Growth hormone (GH) was measured in 215 short children (147 males and 68 females, 123 prepubertal, 92 at early pubertal stages), comparing GH responses to classical pharmacologic stimulation tests and spontaneous GH secretion during sleep. GH secretion during sleep, but not GH responses to stimuli, was higher in early pubertal than in prepubertal subjects. The patients were classified into five groups, according to the agreement between GH responses to stimuli and GH secretion during sleep: group I, normal GH-secreting children; group II, completely GH-deficient; group III, partially GH-deficient; group IV, with normal secretion during sleep and low responses to stimuli; group V, with the reverse situation. 30% of the patients were in groups IV and V, both at prepubertal and early pubertal stages. 46 patients of groups II-V were treated with extracted human GH(hGH). The growth rate was enhanced in groups IV and V, to the same extent as in groups II and III. Four points can be concluded: (1) the rise of GH secretion during sleep is an early event at the onset of puberty; (2) the discrepancy between the GH responses to classical stimuli and GH secretion during sleep are of pathological significance; (3) disturbances of GH secretion might be diagnosed by measuring GH secretion during sleep rather than by using conventional stimulation tests; (4) a trial course of hGH treatment could be proposed in patients with both kinds of discrepancies between GH responses to stimuli and GH secretion during sleep.     

Long-term testosterone supplementation augments overnight growth hormone secretion in healthy older men

Circulating testosterone (T) and GH/IGF-I are diminished in healthy aging men. Short-term administration of high doses of T augments GH secretion in older men. However, effects of long-term, low-dose T supplementation on GH secretion are unknown. Our objective was to evaluate effects of long-term, low-dose T administration on nocturnal GH secretory dynamics and AM concentrations of IGF-I and IGFBP-3 in healthy older men (65-88 yr, n = 34) with low-normal T and IGF-I. In a double-masked, placebo-controlled, randomized study we assessed effects of low-dose T supplementation (100 mg im every 2 wk) for 26 wk on nocturnal GH secretory dynamics [8 PM to 8 AM, Q(20) min sampling, analyzed by multiparameter deconvolution and approximate entropy (ApEn) algorithms]. The results were that T administration increased serum total T by 33% (P = 0.004) and E(2) by 31% (P = 0.009) and decreased SHBG by 17% (P = 0.002) vs. placebo. T supplementation increased nocturnal integrated GH concentrations by 60% (P = 0.02) and pulsatile GH secretion by 79% (P = 0.05), primarily due to a twofold increase in GH secretory burst mass (P = 0.02) and a 1.9-fold increase in basal GH secretion rate (P = 0.05) vs. placebo. There were no significant changes in GH burst frequency or orderliness of GH release (ApEn). IGF-I levels increased by 22% (P = 0.02), with no significant change in IGFBP-3 levels after T vs. placebo. We conclude that low-dose T supplementation for 26 wk increases spontaneous nocturnal GH secretion and morning serum IGF-I concentrations in healthy older men.     

Study of insulin-like growth factor I in human obesity.

In obesity there is a decrease in basal and stimulated GH secretion. IGF-I, which has negative feedback effects on GH secretion, could be the initial mediator of such alterations. We studied IGF-I levels in obese subjects and their relationship to the obesity level and GH secretion. We determined plasma IGF-I, basal and stimulated GH in 30 normal and 30 obese women and related these variables to obesity indices (body mass index, BMI, and % overweight). Baseline plasma GH values were 1.2 +/- 0.3 and 2.3 +/- 0.6 micrograms/l in obese subjects and controls, respectively (NS). Mean peak GH secretion after stimuli were 11.2 +/- 1.4 and 34.4 +/- 5.6 micrograms/l in obese subjects and controls, respectively (p less than 0.001). Plasma IGF-I were 1.0 +/- 0.1 U/ml and 0.7 +/- 0.1 U/l in obese subjects and controls, respectively (NS). There was a significant negative correlation between plasma IGF-I and age (r = -0.55, p less than 0.001) and a significant negative correlation between mean peak GH secretion and weight (r = -0.60, p less than 0.001), BMI (r = -0.64, p less than 0.001) and percentage of ideal body weight (r = -0.67, p less than 0.001). We did not find any correlation between IGF-I and indices of overweight. These data suggest that the reduced GH secretion found in obesity is not related to a negative feedback inhibition by elevated levels of IGF-I and that adiposity is not associated with a decline in IGF-I levels. We confirm the existence of a negative correlation between GH secretion and obesity indices.     

Nocturnal profile of growth hormone secretion during sleep induced by zolpidem: a double-blind study in young adults and children

Overnight blood sampling for repeated growth hormone (GH) assays, regarded as the most physiological assessment of GH status, may induce some disturbances in patients' sleep and then in the evaluation of GH secretion. We studied the influence of a hypnotic drug, zolpidem (10 mg), on nocturnal GH profiles (GH peak, time to first and maximum GH peak, area under the curve, mean integrated concentration) over two nights at a 7-day interval, in a double-blind cross-over design in a group of 12 young adult volunteers (27.9 +/- 4.3 years), and in a group of 12 children (10.8 +/- 2.3 years) with short stature, in a parallel double-blind study. Mean GH profiles showed no difference between zolpidem-treated subjects and placebo-treated controls, either in adults or in children. Although in these experimental conditions, sleep onset latency was significantly reduced with zolpidem in the adult volunteers, the mean time to first GH peak remained unchanged. Furthermore, GH profile did not relate with sleep duration, sleep onset latency or number of awakenings. A hypnotic drug, such as zolpidem, given at bedtime, is therefore devoided of effect on nocturnal GH profile and may be used in young children for overnight blood sampling when needed.     

Plasma levels of insulin-like binding protein-2 in prepubertal short children and its diagnostic value in the evaluation of growth hormone deficiency

AIM: This study was designed to investigate whether determination of plasma insulin-like growth factor (IGF)-binding protein-2 (IGFBP-2) levels could be of benefit in the evaluation of childhood growth hormone (GH) deficiency (GHD). METHOD: A retrospective analysis was performed on 91 prepubertal children referred for investigation of short stature. Maximal GH levels in plasma after provocative stimuli were between 1.0 and 93.0 mU/l, 6 subjects exhibiting peak values of <5 mU/l. Initially a GH peak of 20 mU/l was used as a cutoff limit to define GHD and idiopathic short stature (ISS) patients. The results of GH provocative tests were compared to age- and gender-based standard deviation scores (SDS) of plasma IGFBP-2, IGF-I, IGFBP-3 and the molar ratios of the latter two to IGFBP-2. The respective normative range values for these parameters were determined in plasma samples from 353 healthy children (i.e. 171 girls, 182 boys). RESULTS: Circulating IGFBP-2 levels did not correlate with height SDS, height velocity SDS or the peak GH levels after provocative stimuli. A weak negative relationship was found between IGFBP-2 and IGF-I. Plasma levels of IGFBP-2 in GHD patients were higher than those of ISS children, who had normal levels. Although at the optimal cutoff point of -0.71 SDS 91.5% of the GHD patients were identified correctly, a substantial proportion (71.9%) of the ISS subjects also had IGFBP-2 levels above this limit. The use of various combinations of IGFBP-2, IGF-I, IGFBP-3 and the derived ratios only slightly improved the diagnostic efficiency as compared to the results of the individual tests. Neither IGFBP-2 nor the IGFBP-3/IGFBP-2 and IGF-I/IGFBP-2 ratios were found to be related to the short- (1 year) or long-term (3 years) growth response to GH therapy. CONCLUSION: It is concluded that none of the tests investigated, either alone or in various combinations, are reliable in either predicting the peak GH level after provocative stimuli in prepubertal short children or in predicting their growth response to GH.     

The effect of the somatostatin analogue octreotide on growth hormone secretion in insulin-dependent diabetics without residual insulin secretion.

Growth hormone (GH) hypersecretion is well documented in insulin-dependent diabetes mellitus (IDDM). Somatostatin inhibits GH in acromegalics and healthy subjects although data on its inhibitory effects on high GH levels in IDDM patients are controversial. The effect of treatment with the somatostatin analogue octreotide ("Sandostatin") on GH secretion, IGF1 levels and metabolic control was investigated in insulin-dependent diabetics. Growth hormone and blood glucose were measured at hourly intervals whilst IGF-I was measured every 6 hours during the 24-h period before and after 7 days' treatment with octreotide (200 micrograms subcutaneously three times daily) in 10 C-peptide negative diabetics. Octreotide significantly reduced mean 24 h GH profile (7.2 +/- 0.7 mU/L before; 5.2 +/- 0.5 mU/L on octreotide, p less than 0.01), IGF-I levels (0.62 +/- 0.06 before; 0.47 +/- 0.05 on octreotide, p less than 0.005) mean 24 h blood glucose (14.4 +/- 0.5 mmol/L before; 12.6 +/- 0.4 mmol/L on octreotide, p less than 0.001) and daily insulin requirements (44.8 +/- 3.0 IU before; 37.2 +/- 3.0 IU on octreotide, p less than 0.02). The shape of 24 h GH profile curve changed significantly on octreotide treatment (p less than 0.05) when it consisted of three nadirs and three peaks closely linked with the time of octreotide administration. Moderate (abdominal discomfort) to severe hypoglycaemia) transient side effects have been observed in all treated patients. The results of this study showed that short-term treatment with octreotide given s. c. every eight hours modulates the pattern of GH secretion in C-peptide negative insulin-dependent patients.(ABSTRACT TRUNCATED AT 250 WORDS)     

The capacity to increase GH secretion at puberty reflects the severity of GH deficiency.

This study evaluates the effect of the spontaneous pubertal increase in sex steroids on GH secretion in GH-deficient patients. Fifteen patients (10 boys, 5 girls) with idiopathic isolated GH deficiency diagnosed before puberty (GH peak < 8 micrograms/l after 2 arginine insulin stimulation tests) were reevaluated for their GH secretion using the same test after completion of their hGH therapy and puberty. Their ages at diagnosis and at the last evaluation were 8.2 +/- 0.7 (SE) (range 4.9-14.9) and 17.8 +/- 0.3 years (15-23), respectively. The data at diagnosis and at last evaluation showed that (1) the mean height increased from -4 +/- 0.3 to -2.5 +/- 0.3 SD (p < 0.01), (2) the mean GH peak increased from 4.4 +/- 0.3 (1.6-8) to 7.6 +/- 0.8 micrograms/l (2-13.2, p < 0.01); at the last evaluation, 8/15 patients had GH peak > 8 micrograms/l and (3) the mean plasma insulin-like growth factor I increased from 0.28 +/- 0.05 to 0.42 +/- 0.03 U/ml (n = 6, p < 0.05). The mean increase in the GH peak was 3.2 micrograms/l (-3 to 10.6). It was negatively correlated with the degree of growth retardation at diagnosis (r = -0.74, p < 0.005). We conclude that the increase in the GH peak at puberty in patients with GH deficiency reflects the severity of GH deficiency and that a corrective factor of the cutoff number is necessary for the diagnosis of GH deficiency in puberty.     

Assessing short-statured children for growth hormone deficiency

AIM: To optimize the workup of short-statured children by defining the most appropriate tools for diagnosing growth hormone (GH) deficiency. METHODS: Patients were assigned to prepubertal (n = 113) or pubertal (n = 112, including 25 boys primed with testosterone) age groups. Mean plasma GH concentration during sleep, GH peak after provocative test, and insulin-like growth factor I (IGF-I) were measured in a single evaluation. RESULTS: The mean GH concentration during sleep was more often normal (n = 155) than the GH peak after provocative tests (n = 105) or the IGF-I concentration (n = 88). Prepubertal patients with a normal body mass index (BMI) had mean GH concentrations during sleep that correlated positively with height, growth rate, GH peak after provocative tests, and IGF-I (p < 0.0005 for all) and negatively with the difference between target and patient heights (p = 0.01) and BMI (p < 0.05). Pubertal patients with a normal BMI had a mean GH concentration during sleep that correlated positively with GH after provocative tests (p < 0.0001) and IGF-I (p < 0.005). Mean GH concentration during sleep and IGF-I concentration for boys primed with testosterone were more often normal (n = 23) than the GH peak after provocative tests (n = 14). All 9 patients with pituitary stalk interruption had low IGF-I concentrations; 1 patient had a normal GH peak after provocative test, and 2 patients had normal mean GH concentrations during sleep. CONCLUSIONS: Measuring the GH concentration during sleep and priming boys with pubertal delay can help to exclude idiopathic GH deficiency. Magnetic resonance imaging is needed to exclude anatomic abnormalities when GH and/or IGF-I concentrations are low.     

Food intake of children with short stature born small for gestational age before and during a randomized GH trial

Parents of short children born SGA often report that their children have a serious lack of appetite and a low food intake. In this study we investigated food intake, by using a standardized 7-day food questionnaire, in 88 short SGA children before start of GH treatment. The intake was compared with the recommended daily intake (RDI) of age-matched children. We also compared the food intake of GH-treated children (n=62) with randomized controls (n=26) after 1 year of GH treatment. In addition, we evaluated the effect of food intake and GH treatment on body composition and serum levels of IGF-I, IGFBP-3 and leptin. Our study shows that caloric intake, fat and carbohydrate intake of short SGA children aged 5.9 (1.6) years was significantly lower compared to the RDI for age-matched children. One year of GH treatment resulted in a significant increase of caloric, fat, carbohydrate and protein intake compared to baseline. Compared to randomized controls, caloric, carbohydrate and protein intake increased significantly after 1 year of GH treatment. Short SGA children had significantly lower SDS scores for LBM, fat mass, skinfold (SF) and BMI compared to age-matched references. They also had significantly lower serum IGF-I, IGFBP-3 and leptin levels. GH treatment resulted in a significant increase of height, LBM, BMI, IGF-I and IGFBP-3 SDS and a significant decrease of SF SDS and leptin SDS. In conclusion, our study shows that short SGA children have indeed a lower food intake than age-matched controls. During GH treatment the food intake increased significantly compared to baseline in contrast to the randomized control group.