Final height in children with idiopathic growth hormone deficiency treated with a fixed dose of recombinant growth hormone

There is no consensus regarding the optimal dosing of recombinant human growth hormone (rhGH) for children with growth hormone deficiency (GHD). Our objective was to evaluate the final adult height (FAH) in children with idiopathic GHD treated with a fixed rhGH dose of 0.18 mg/kg/week. We reviewed all charts of patients with idiopathic GHD treated with rhGH since 1985 who reached FAH. Ninety-six patients were treated for an average of 5.4 years. The mean age was 11.9 years, the mean height -2.87 standard deviation score (SDS) and the mean FAH was -1.04 SDS. Females had a lower predicted adult height than males at the initiation of therapy (-2.0 vs. -1.01 SDS; p = 0.0087) but a higher FAH - predicted adult height (1.08 vs. 0.04 SDS; p = 0.0026). In multiple regression analysis, the FAH SDS was positively related to the midparental height SDS, the height SDS at GH initiation and growth velocity during the first year of therapy, and negatively correlated with peak GH and bone age at initiation (r(2) = 0.51; p < 0.005). Treatment of children with idiopathic GHD with a fixed dose of 0.18 mg/kg/week rhGH is sufficient to reach FAH within 2 SDS of the normal population range (84%) with an average FAH within -0.5 SDS of midparental height.     

Metabolic consequences of growth hormone treatment in paediatric practice

No metabolic side-effects of clinical significance have been reported during a 5-year study of growth hormone (GH) therapy in children with GH deficiency, Turner syndrome, idiopathic short stature or chronic renal insufficiency. In particular, insulin levels increase but remain within the normal range, as do glucose and haemoglobin A(1c). A recent study showed that the effects of growth on insulin sensitivity in prepubertal children with idiopathic short stature represent the changes in carbohydrate tolerance observed during normal adolescence. Thus, GH treatment may lead to prolongation of the physiological state of insulin resistance observed in normal puberty. Insulin levels during the fasting state and 2 h after a standard glucose load showed no further rise after the first 3 years of continuous GH therapy. The hyperinsulinaemia observed during GH therapy may, therefore, amplify the anabolic effects of insulin on protein metabolism during puberty.     

Bone age progression during the first year of growth hormone therapy in pre-pubertal children with idiopathic growth hormone deficiency, Turner syndrome or idiopathic short stature, and in short children born small for gestational age: analysis of data from KIGS (Pfizer International Growth Database)

BACKGROUND/AIMS: The beneficial effects of growth hormone (GH) therapy on statural growth in children are well established, but the effects on skeletal maturation are less clear. The progression of bone age (BA) was therefore studied during the first year of GH treatment in pre-pubertal children with idiopathic GH deficiency (GHD), Turner syndrome (TS) or idiopathic short stature (ISS), and in short pre-pubertal children born small for gestational age (SGA). METHODS: Cross-sectional data on 2,209 short children with idiopathic GHD, 694 with TS, 569 with ISS and 153 with SGA were analysed. Longitudinal data were also analysed from 308 children with idiopathic GHD, 99 with TS, 57 with ISS and 29 with SGA. All patients included in the study were enrolled in KIGS (Pfizer International Growth Database) and were being treated with recombinant human GH (Genotropin). BA was assessed using the Greulich and Pyle method at baseline and after 1 year of GH therapy. RESULTS: In all groups of patients the mean progression of BA was 1 year during the year of GH therapy, although there was considerable individual variation. Progression of BA was not correlated with chronological age, BA, height SD score (SDS) or body mass index SDS at the onset of GH therapy. There was also no consistent effect of the GH dose on BA progression. CONCLUSION: Progression of BA appears to be normal in patients receiving GH in these diagnostic groups, at least over the first year of treatment in pre-puberty.     

Physiological growth hormone secretion in children with short stature and intra-uterine growth retardation

31 prepubertal children with short stature [mean height standard deviation score (SDS) -2.84] and low birth weight (mean -2.82 SDS) were studied. Mean age was 6.0 years and mean height velocity SDS was -0.76. Patients were classified as having either the clinical characteristics of Russell-Silver syndrome (RSS) (4 F, 13 M) or not (4 F, 10 M). All children had an overnight profile of spontaneous growth hormone (GH) secretion. 4 children achieved a maximum GH concentration of less than 20 mU/l. 9 children with RSS secreted only one large GH peak during the night. Most of the non-RSS group had normal GH pulse frequency but 3 boys had a fast-frequency pattern. Abnormal GH secretion may contribute towards growth failure in children with low birth weight/RSS.     

Insulin-like growth factors and their binding proteins in children born small for gestational age: implication for growth hormone therapy

The insulin-like growth factors (IGFs) and their binding proteins (IGFBPs) are important regulators of growth and metabolism and are the key mediators of the actions of growth hormone (GH). Children born small for gestational age (SGA) have a host of medical problems including an increased risk of poor growth later in life, a tendency to develop metabolic abnormalities and a high incidence of learning disabilities. IGFs and related molecules may be linked to all of these concerns. Mouse models of IGF-I and IGF-II deficiencies have phenotypes reminiscent of human SGA, including slow growth, insulin resistance, and mental dysfunction. Humans with IGF-I mutations are born SGA and exhibit very poor subsequent growth, metabolic syndrome and mental retardation. Current management of children born SGA who present with growth failure during childhood includes treatment with GH. SGA children usually have growth factor levels within the normal range; however, as a group, they display lower IGFBP-3 levels in relation to their IGF-I levels. GH is effective in improving growth in children born SGA, but higher doses of GH are required to achieve optimal outcome, suggesting a component of GH insensitivity in SGA children. As in other indications for GH, a rational monitoring approach (focusing on maintaining IGF levels in the high normal range) is prudent.     

Validity of height velocity as a diagnostic criterion for idiopathic growth hormone deficiency and Turner syndrome.

A deflecting growth curve over several years is sometimes the only indication for the possible presence of a growth disorder. In this study we looked at the potential diagnostic role of long-term downward deflection of the growth curve. It reports on the diagnostic validity of height velocity over 1, 2 or 3 years for isolated idiopathic growth hormone deficiency and for Turner syndrome in prepubertal children with a height that is still above -2.5 standard deviation scores (SDS). 1-year height velocity was found to have no diagnostic value because of an almost complete overlap of height velocity distributions with normal prepubertal children. However, height velocity over 3 years was found to have an acceptable validity in children 5-12 years old. In this age range a change in height SDS of -0.75 can be used as a valid criterion for further examination of karyotype and GH secretion capacity even if there are no other clear signs of a particular growth disorder.     

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.     

The effect of growth hormone therapy on craniofacial growth and dental maturity in children with Down syndrome.

Craniofacial growth was evaluated 3 years after termination of growth hormone (GH) therapy in ten Down syndrome (DS) children. The control group consisted of 16 age-matched children with DS. The treatment started at 6-9 months of age, and the duration was 36 months. There were no statistically significant differences in craniofacial development between DS children treated with GH or DS children not treated. In conclusion, the results of this study indicate that GH therapy for 36 months in children with DS did not change the craniofacial morphology compared to a group of DS children not given GH.     

Genetic disorders in the growth hormone - insulin-like growth factor-I axis

In the last few years, our knowledge of genetically determined causes of short stature has greatly increased by reports of challenging patients, who offered the opportunity to study genes that play a role in growth. Since the first paper that showed the etiology of Laron syndrome [Godowski PJ, et al: Proc Natl Acad Sci USA 1989;86:8083-8087], many mutations in the growth hormone (GH) receptor have been identified. Recently, new mutations or deletions have been found in several components of the GH-insulin-like growth factor-I (IGF-I) axis: a homozygous mutation of the GH1 gene, resulting in a bio-inactive GH; mutations in the STAT5b gene, which plays a major role in the GH signal transduction; a homozygous missense mutation in the IGF-I gene; heterozygous mutations in the IGF-I receptor gene and a homozygous deletion of the acid-labile subunit gene. In this mini review, we describe the clinical and biochemical features of these genetic defects. Genetic analysis has become essential in the diagnostic workup of a patient with short stature. However, regarding the time consuming nature of molecular analysis, it is important to carefully select the patient for specific genetic evaluation. To help in this selection process, we developed flowcharts, based on the recently described patients, that can be used as guidelines in the diagnostic process of patients with severe short stature of unknown origin.     

Influence of growth hormone on thymic endocrine activity in humans

The thymus produces humoral factors that induce the proliferation and differentiation of T cells which are responsible for cell-mediated immunity. Experimental data have suggested that this thymic hormone production is modulated by the neuroendocrine network and, in particular, by growth hormone (GH) and thyroid hormones. To study the role played by GH in thymic endocrine activity in humans, the circulating level of one of the best known thymic peptides, i.e. thymulin (Zn-FTS), has been determined, after a washout period of 2 weeks without GH treatment, in GH-deficient children before and after a single injection of GH. The basal thymulin level is consistently lower in GH-deficient children than in healthy age-matched controls. A single injection of GH induces a significant increment of the thymulin level for at least 48 h. Since thymulin activity may also depend on zinc bioavailability, on thyroid hormone turnover and on the eventual presence of thymulin-inhibitory substances, all these aspects have been checked. No supporting evidence regarding the existence of these kinds of interferences in GH-deficient children has been substantiated. A positive correlation has been found between the serum level of insulin-like growth factor I, but not of GH, and thymulin activity. These data suggest that GH may directly or indirectly modulate the thymic endocrine function in humans. Whether and to what extent such a modulation is relevant to the functioning of the immune system remains to be ascertained.     

Short-term effect on growth of two doses of GRF 1-44 in children with growth hormone deficiency: comparison with growth induced by methionyl-GH administration

In a double-blind study 12 prepubertal children with idiopathic growth hormone (GH) deficiency were treated with growth hormone releasing factor (GRF) 1-44 in a dosage of 7.5 or 15 micrograms/kg body weight, administered once a day subcutaneously. With 7.5 micrograms/kg the average growth velocity increased from 2.5 to 4.6 cm/year, an insufficient response. With the higher dosage the average growth velocity increased from 2.7 to 7.0 cm/year, a similar increase as observed with GH therapy in subsequent periods. In 3 of the 6 children treated with the higher dose appropriate catch-up growth was observed. The growth response of the lower leg length was not always consistent with the statural growth response.     

The use of growth hormone-releasing hormone in the diagnosis and treatment of short stature

We have assessed the role of growth hormone-releasing hormone (GHRH) as a diagnostic test in 40 children and young adults with growth hormone deficiency (GHD), principally using the GHRH(1-29)NH2 analogue. Following 200 micrograms GHRH as an acute intravenous bolus, serum GH rose to normal or just subnormal levels in 13 out of 17 children with structural lesions, and in 8 of 14 patients with idiopathic GHD or panhypopituitarism. Of 9 children (mean age 12 years) with GHD following treatment with cranial irradiation for nonendocrine tumours, all responded acutely to GHRH. 12- and 24-hour infusions with GHRH(1-29)NH2, and 1- and 2-week treatments with twice-daily subcutaneous GHRH(1-29)NH2, showed persistent stimulation of GH release. It is concluded that many children with GHD of diverse aetiology will respond both acutely and chronically to treatment with GHRH.     

Spontaneous prolactin secretion in growth hormone-deficient children.

OBJECTIVE: To establish the spontaneous nocturnal prolactin (PRL) release in relation to growth hormone (GH)-deficient children and idiopathic short-stature children (ISS). METHODS: A total of 32 prepubertal children (11 girls, 21 boys) aged between 3 and 12 years were studied retrospectively and sorted according to diagnosis: idiopathic GH deficiency (GHD, n = 9), neurosecretory deficiency of GH secretion (NSD, n = 10) and ISS (n = 13). Nocturnal spontaneous hormone secretion was studied by intermittent venous sampling. Secretion profiles and copulsatility were analyzed using Pulsar and AnCoPuls software. RESULTS: (median, range in mug/l): Children with GHD and NSD had significantly lower GH and area-under-the-curve (AUC) levels than normal children (p < 0.001), whereas ISS children showed normal values. In contrast, prolactin levels were significantly higher (p < 0. 05) in children with GHD and NSD (11.1, 4.9 - 13.0 and 10.3, 8. 8 - 19. 6, respectively) compared to the ISS children (8.0, 4.9 - 13.0). In addition, prolactin AUC and peak height were higher (p < 0.05) in GH-deficient patients, whereas all other secretion parameters were the same. Correlation and copulsatility analysis revealed no evidence for a direct relation between PRL and GH secretion. CONCLUSIONS: PRL secretion is significantly higher in children with GHD and NSD compared to ISS children but PRL and GH show no copulsatile secretion pattern.     

Resolution of apparent growth hormone-dependent growth failure during puberty: a case report

A prepubertal boy with apparent growth hormone (GH)-dependent growth failure displayed a marked increase in growth velocity, normal GH responses to arginine/insulin infusion and a fourfold increase in spontaneous 24-hour GH secretion following the onset of normal puberty. The case supports earlier observations of a transient form of GH insufficiency in some short prepubertal children, but represents the first evidence that puberty restores spontaneous as well as stimulated GH secretion in such patients.     

Growth response to recombinant human growth hormone (GH) in children with idiopathic growth retardation by level of maximum GH peak during GH stimulation tests

Due to their lack of reproducibility, it is unlikely that GH stimulation tests can provide reliable diagnostic information to distinguish partial isolated GH deficiency (GHD) from idiopathic short stature (ISS). We hypothesized that the classical distinction between these groups, essentially based on stimulatory GH peaks, is artificial and that, as a consequence, the average response to GH treatment will not be different between them. The hypothesized lack of prognostic validity of stimulatory GH peaks was studied in 435 prepubertal children with nonorganic growth retardation. Children were categorized as 'severe GHD', 'partial GHD' or 'ISS', if the maximum rise in their serum GH during two GH stimulation tests was 0--10 mU/l, 10--20 mU/l, or >20 mU/l, respectively. Children with 'partial GHD' had short-term (1- and 2-year) and long-term (till final adult height) growth responses similar to those of children with ISS, significantly lower than the response seen in children with 'severe GHD'. In children with stimulatory GH peaks >10 mU/l, including those currently considered partially GH deficient, the maximum GH peak was not a significant determinant of growth response in the short or the long term. In conclusion, 'partial GHD' is ill defined and cannot be distinguished from ISS based on the currently applied auxological or GH stimulation test criteria alone. More research is required for better identification of (all) children who will respond to GH treatment, whether or not GH deficient.     

Dosing of growth hormone in growth hormone deficiency

Growth hormone (GH) treatment of GH-deficient (GHD) children is to a certain extent standardized worldwide. Recombinant 22 kDa GH is injected once daily by the subcutaneous route, mostly in the evening. The amount of GH injected (calculated per kg body weight or body surface area, expressed in terms of IU or mg) in prepubertal children mimics the known production rate (approximately 0.02 mg [0. 06 IU]/kg body weight per day). However, there is a wide variation in dosage, the reasons for which are partly unknown and partly due to national traditions and regimes imposed by authorities regulating reimbursement. The situation during puberty is less standardized, with most clinicians still not increasing the dosage according to known production rates. The results of these approaches in terms of adult height outcome are not always satisfactory. In order to achieve optimal height development during childhood, puberty and adulthood, strategies must be developed to individualize GH dosing according to set therapeutical goals taking into account efficacy, safety and cost. The implementation of prediction algorithms will help us to reach these goals. In addition, other response variables will have to be monitored during treatment in order to correct for deficits resulting from GHD.     

Proteins related to lipoprotein profile were identified using a pharmaco-proteomic approach as markers for growth response to growth hormone (GH) treatment in short prepubertal children

Background  

The broad range in growth observed in response to growth hormone (GH) treatment is mainly caused by individual variations in both GH secretion and GH sensitivity. Individual GH responsiveness can be estimated using evidence-based models that predict the response to GH treatment; however, these models can be improved. High-throughput proteomics techniques can be used to identify proteins that may potentially be used as variables in such models in order to improve their predictive ability. Previously we have reported that proteomic analyses can identify biomarkers that discriminate between short prepubertal children with idiopathic short stature (ISS) who show good or poor growth in response to GH treatment. In this study we used a pharmaco-proteomic approach to identify novel factors that correlate with the growth response to GH treatment in prepubertal children who are short due to GH deficiency or ISS. The study included 128 short prepubertal children receiving GH treatment, of whom 39 were GH-deficient and 89 had ISS. Serum protein expression profiles at study start and after 1 year of GH treatment were analyzed using SELDI-TOF. Cross-validated regression and random permutation analyses were performed to identify significant correlations between protein expression patterns and the 2-year growth response to GH treatment.     

Effects of growth hormone in patients with chronic renal failure: experience in children and adults

Recombinant human growth hormone (GH) has proven effective in promoting growth in short children with chronic renal failure before and after renal transplantation. The action of GH and its mediator insulin-like growth factor 1 on body composition, protein, glucose and bone metabolism offers additional therapeutic options. One might be the improvement of the catabolic state in adults with end-stage renal failure. In few pilot studies and two placebo-controlled studies of 6 months duration, GH treatment in adults on dialysis showed clear anabolic effects resulting in a significant increase in lean body mass.     

Treatment of growth failure in juvenile chronic arthritis

We retrospectively assessed linear growth and final height in a group of 24 patients suffering from juvenile idiopathic arthritis (JIA) during childhood, receiving steroid therapy. In these patients, a significant loss of height (-2.7 +/- 1.5 SDS) occurred in the first years of the disease which was positively correlated with prednisone therapy duration. After remission of the disease and prednisone discontinuation, most of the patients (70%) had catch-up growth but 30% had a persistent loss of height. Their mean final height was strongly correlated with their mean height at the end of steroid therapy and was significantly different between the group of patients with catch-up growth (-1.5 +/- 1.6 SDS) and the group without catch-up growth (-3.6 +/- 1.2 SDS). This pattern of growth observed in JIA patients should help us to define strategies of GH treatment in these patients in order to improve their final height. We have previously reported the beneficial effects on growth and body composition of a 1-year GH treatment in a group of 14 growth-retarded patients suffering from juvenile idiopathic arthritis, receiving glucocorticoid therapy. These patients (n = 13) were treated again with GH at the same dosage (0.46 mg/kg/week) for another 3-year period. GH treatment markedly increased growth velocity in these patients, but had a minor effect on SDS height suggesting that these children will remain short at adult age. Using GH earlier in these patients during the course of their disease may prevent growth deterioration and metabolic complications induced by chronic inflammation and long-term steroid therapy.     

Combination therapy with acipimox enhances the effect of growth hormone treatment on linear body growth in the normal and small-for-gestational-age rat

Growth hormone (GH) therapy is often associated with adverse side effects, including impaired insulin sensitivity. GH treatment of children with idiopathic short stature does not lead to an optimized final adult height. It has been demonstrated that FFA reduction induced by pharmacological antilipolysis can stimulate GH secretion per se in both normal subjects and those with GH deficiency. However, to date, no investigation has been undertaken to establish efficacy of combination treatment with GH and FFA regulators on linear body growth. Using a model of maternal undernutrition in the rat to induce growth-restricted offspring, we investigated the hypothesis that combination treatment with GH and FFA regulators can enhance linear body growth above that of GH alone. At postnatal day 28, male offspring of normally nourished mothers (controls) and offspring born with low birth weight [small for gestational age (SGA)] were treated with saline, GH, or GH (5 mg.kg(-1).day(-1)) in combination with acipimox (GH + acipimox, 20 mg.kg(-1).day(-1)) or fenofibrate (GH + fenofibrate, 30 mg.kg(-1).day(-1)) for 40 days. GH plus acipimox treatment significantly enhanced linear body growth in the control and SGA animals above that of GH, as quantified by tibial and total body length. Treatment with GH significantly increased fasting plasma insulin, insulin-to-glucose ratio, and plasma volumes in control and SGA animals but was not significantly different between saline and GH-plus-acipimox-treated animals. GH-induced lipolysis was blocked by GH plus acipimox treatment in both control and SGA animals, concomitant with a significant reduction in fasting plasma FFA and insulin concentrations. This is the first study to show that GH plus acipimox combination therapy, via pharmacological blocking of lipolysis during GH exposure, can significantly enhance the efficacy of GH in linear growth promotion and ameliorate unwanted metabolic side effects.