High-dose growth hormone (GH) treatment in prepubertal GH-deficient children

Yokoya S, Araki K, Igarashi Y, Kohno H, Nishi Y, Hasegawa Y, Fujita K, Iwatani N, Tachibana K, Ohyama Y, Seino Y, Satoh M, Fujieda K, Tanaka T. High-dose growth hormone (GH) treatment in prepubertal GH-deficient children. Acta Pædiatr 1999; Suppl 428: 76–9. Stockholm. ISSN 0803–5326
Two clinical studies were conducted to determine the effect of different doses of growth hormone (GH) on prepubertal growth in GH-deficient boys. In one study, GH doses of 1.0 and 1.5 IU/kg/week (0.33 and 0.5 mg/kg/week) were given to groups of five children and compared with a conventional Japanese dose of 0.5 IU/kg/week (0.17 mg/kg/week) in 15 children. A significant dose-dependent increase in height velocity occurred in the first year of treatment, but differences between doses were not significant thereafter. In a second study, GH was administered to ten boys at a dose of 0.5 IU/kg/week for the first year, 0.75 IU/kg/week for the second year, 1.0 IU/kg/week for the third year and 0.5 IU/kg/week for the fourth and subsequent years (0.17, 0.25, 0.33 and 0.17 mg/kg/week, respectively). During the second and third years of GH treatment, these boys had significantly higher growth rates than controls, who were given GH at 0.5 IU/kg/week (0.17 mg/kg/week) throughout, indicating successful reduction in'waning'of the treatment effect. At the end of the fourth year, the different protocols from the two studies had both resulted in a greater height SDS than the controls, and did not advance bone maturation. In conclusion, these protocols may be effective in increasing prepubertal height gain in children with GH deficiency. □ Growth hormone, growth hormone deficiency, high dose     

High-dose growth hormone (GH) treatment in prepubertal GH-deficient children

Two clinical studies were conducted to determine the effect of different doses of growth hormone (GH) on prepubertal growth in GH-deficient boys. In one study, GH doses of 1.0 and 1.5 IU/kg/week (0.33 and 0.5 mg/kg/week) were given to groups of five children and compared with a conventional Japanese dose of 0.5 IU/kg/week (0.17 mg/kg/week) in 15 children. A significant dose-dependent increase in height velocity occurred in the first year of treatment, but differences between doses were not significant thereafter. In a second study, GH was administered to ten boys at a dose of 0.5 IU/kg/week for the first year, 0.75 IU/kg/week for the second year, 1.0 IU/kg/week for the third year and 0.5 IU/kg/week for the fourth and subsequent years (0.17, 0.25, 0.33 and 0.17 mg/kg/week, respectively). During the second and third years of GH treatment, these boys had significantly higher growth rates than controls, who were given GH at 0.5 IU/kg/week (0.17 mg/kg/week) throughout, indicating successful reduction in 'waning' of the treatment effect. At the end of the fourth year, the different protocols from the two studies had both resulted in a greater height SDS than the controls, and did not advance bone maturation. In conclusion, these protocols may be effective in increasing prepubertal height gain in children with GH deficiency.     

Confirming the diagnosis of growth hormone deficiency (GHD) and transitioning the care of patients with childhood-onset GHD

Growth hormone deficiency (GHD) diagnosed in childhood may persist into adult life. After attainment of final height, retesting of the patient's growth hormone-insulin-like growth factor (GH-IGF) axis using the adult GHD diagnostic criteria should be performed after an appropriate interval of 1-3 months off GH therapy. At the time of retesting, other pituitary hormones and serum IGF-I levels should also be measured. The opportunity should be taken to assess body composition, bone mineral density, and fasting lipid and insulin levels. Patients with severe, long-standing, multiple pituitary hormone deficiency, genetic defects, or severe organic GHD can be excluded from GH retesting. When the diagnosis of adult GHD is established, continuation of GH therapy can be recommended unless there is a known risk of diabetes mellitus or malignancy. The patient's transition to GH replacement in adulthood should be arranged as a close collaboration between the pediatric and adult endocrinologists, who should discuss the reinitiation of treatment with the patient.     

Eficacia y seguridad del tratamiento sustitutivo en el déficit aislado de hormona del crecimiento

IntroductionGrowth in patients with isolated growth hormone (GH) deficiency is heterogeneous despite treatment due to the low specificity of diagnostic tests, making it necessary to define efficacy variables.AimsTo evaluate efficacy of hormone replacement therapy in children with isolated GH deficiency.MethodsObservational-ambispective study of patients treated in our department in the last 14 years for isolated GH deficiency. This was defined as a GH level less than 7.4 mg/dl in response to 2 stimulation tests in patients with height < 2SD and a decreased growth rate.ResultsThe study included a total 97 patients, of whom 69% were boys. The large majority (89.58%) achieved final height. None of them had side effects. The median dose of GH used was 0.028 mg/kg/day (0.03-0.025). There was a gain of 1.17 SD in final height. Around three-quarters (71.13%) of the patients were reassessed in adulthood, of whom 39.4% maintained the deficiency, and 79.31% achieved target range height. Target height, estimated height, and the total pubertal gain were positively correlated with final height, while the bone age/chronological age ratio and the initial insulin-like growth factor-1 showed a negative correlation.ConclusionsA majority of patients reached target size, although only a few of them maintained the deficiency in adulthood. Target size, estimated adult height, and pubertal variables are directly related to adult height, while bone age/chronological age and insulin-like growth factor-1 were inversely related, and these can be used as efficacy variables. No adverse effects were observed in the sample with the doses used for the treatment.     

Acquisition of bone mass in normal individuals and in patients with growth hormone deficiency

Children and adolescents with growth hormone (GH) deficiency (GHD) have reduced bone turnover and bone mass in comparison with normal individuals. GH replacement therapy stimulates bone turnover and improves bone mass during childhood and adolescence. At final height, patients with GHD treated with GH have normal mean values of bone mass, but some patients have reduced lumbar BMD (Z score <1) with an increased susceptibility to fractures. Children and adolescents with GHD have approximately a fourfold decreased fracture frequency during treatment in comparison with controls. The changes of bone mass during the transition to adulthood in patients with GHD who discontinued GH treatment after final height are not defined. An increase of lumbar BMD after final height has been reported until 2 years after discontinuation of GH treatment; this could be the result of a spontaneous progression towards peak bone mass or of a persisting effect of GH treatment on bone mass accumulation. GH has an important role in the accrual of bone mass during childhood and adolescence, but the impact of GHD on bone mass during the transiton to adulthood is unknown.     

Growth response to growth hormone therapy following cranial irradiation

The growth response to growth hormone (GH) therapy has been studied in 12 children who received irradiation to the cranium alone either for brain gliomas, distant from the hypothalamic-pituitary axis, or as prophylaxis against CNS leukaemia. Seven children have completed GH treatment (mean duration 4 years) and five are presently on GH (mean duration 1.2 years). This response has been compared to that seen in 14 children with isolated idiopathic GH deficiency (IGHD), following GH therapy. Before treatment, the cranially irradiated patients (C-PRGHD) had higher standard deviation scores (SDS) for standing height, sitting height and leg length, and less bone age (BA) retardation, but started treatment at a similar age, and with a similar pre-treatment growth velocity and GH peak to standard provocative tests, compared to IGHD patients. GH produced a significant and similar increase in growth velocity (cm/year and SDS for BA) over the first 2 years' treatment in both groups. However C-PRGHD patients entered puberty and thus completed growth earlier than the IGHD group. As a result, cranially-irradiated children showed no change in height SDS with GH therapy, compared to catch-up growth in IGHD. Nevertheless, GH has enabled C-PRGHD patients to maintain their centile position and to achieve a more acceptable final height.Abbreviations GH growth hormone - IGHD idiopathic growth hormone deficiency - C-PRGHD post cranial-irradiation growth hormone deficiency - SDS standard deviation score - BA bone age - ALL acute lymphatic leukaemia - TSH thyroid stimulating hormone - CA chronological age - HA height age     

Final height of growth hormone-treated patients with growth hormone deficiency: the North American experience

Hintz RL. Final height of growth hormone-treated patients with growth hormone deficiency: the North American experience. Acta Pædiatr 1999; Suppl 428: 70–1. Stockholm. ISSN 0803–5326
The results of treatment of growth hormone (GH)-deficient patients with recombinant GH are better than the results of treatment with pituitary GH. The reasons for this improvement include higher dosages, more consistent treatment, and daily administration. Under ideal circumstances, final height in patients with GH deficiency (GHD) can be within the normal range for adult height with GH treatment, and brought close to their target height. To achieve this result, it is important to diagnose and treat GHD early, use adequate doses of GH, and continue treatment until final height. □ Growth hormone, growth hormone deficiency, final height     

Gonadotropin releasing hormone analogue therapy in children with isolated growth hormone deficiency: final height benefit from postponing puberty?

Although growth hormone (GH) treatment has improved final height prognosis in children with GH deficiency (GHD), adult heights are still disappointing. Final height could be improved by increasing the duration of puberty and in this way increasing total pubertal height gain. Many studies have been published on the effect of gonadal suppression, mostly by gonadotropin releasing hormone (GnRH) analogues, on final height in children with GHD. Because of the different methodologies used in these studies, results are difficult to compare. Both positive and marginal effects on final height have been reported; however, patient numbers are limited. Children with GHD who start puberty at a relatively young age and who have a poor predicted adult height, can benefit from the addition of GnRH analogues. From previous studies, we might conclude that when there is a positive effect, height benefit is marginal. However, additional prospective, randomized controlled trials are needed to further elucidate whether delaying puberty is indicated in children with GHD to improve final height.     

Responses of somatotropin to stimuli after brief administration of estradiol in short children

Ethinyl estradiol has been administered orally, 100 micrograms per day during three days, to enhance the growth hormone (GH) response to usual pharmacological stimuli. 102 prepubertal short patients aged 2 to 17 years with height between 2 to 6 SD below the mean, were studied. Human growth hormone (hGH) treatment was given only to those patients whose GH response was still below 10 ng/ml after estradiol. Under hGH treatment, their growth rate increased twofold, as much in patients with partial GH deficiency as in those with complete GH deficiency. It is concluded that the lack of GH response after estradiol priming contributes to the assessment of the indication for treatment with hGH. However, since it has not been possible to give this treatment to very short children whose GH response became normal after priming, this study does not allow to preclude the effect of hGH in such conditions. Thus estradiol priming must not be included among the practical criteria leading to therapeutic decision in doubtful cases.     

Evaluation of growth hormone secretion after completion of therapy

BACKGROUND: Growth hormone (GH) reserve in young adults previously diagnosed as having GH insufficiency, who were treated with human (h)GH replacement in childhood needs confirmation in adulthood. METHODS: Nine patients (seven males, two females; two empty cella, one hypoplasia of the hypophysis and six with idiopathic GH deficiency) diagnosed as having GH insufficiency by the insulin tolerance test (ITT) and dopamine stimulation test in childhood (mean age 12.8+/-2.6 years) were retested at completion of linear growth (mean age 21.0+/-3.0 years), 4.6+/-1.6 years after discontinuation of hGH therapy. RESULTS: At the initial diagnosis, seven had complete and two had partial GH deficiency. At diagnosis, the mean peak GH response to ITT and dopamine was 4.8+/-4.08 and 3.4+/-2.9 mU/L, respectively. At retesting, the mean GH response to ITT and dopamine stimulation was 3.5+/-2.5 and 3.3+/-3.1 mU/L, respectively (P=0.91 and 0.96, respectively). During hGH therapy, mean height velocity increased from 3.5+/-1.9 cm/year at diagnosis to 9.9+/-3.64 cm/year during the first year (P=0.002). One of nine children diagnosed as having GH insufficiency who was treated with hGH replacement had normal growth hormone secretion at completion of linear growth. CONCLUSIONS: All GH-insufficient children should be retested after completion of their hGH treatment and linear growth to identify those who are truly GH insufficient and who may benefit from GH therapy in adulthood.     

Growth hormone for short stature not due to classic growth hormone deficiency

The advent of recombinant DNA technology has resulted in potentially unlimited supplies of growth hormone. Sufficient quantities are now available not only for the long-term, uninterrupted treatment of GH-deficient children but potentially for the treatment of non-GH-deficient patients with other short stature or growth attenuating disorders. Short-term studies have demonstrated an improvement in the growth rates of subjects with isolated short stature, Turner syndrome, and chronic renal failure; and additional studies are under way to assess the efficacy of GH therapy of other short stature syndromes. However, the long-term efficacy and possible adverse effects of GH treatment in these situations is not known. Until there has been more experience, GH deficiency should remain the primary indication for GH treatment. Growth hormone should not be considered routine therapy for other conditions associated with or resulting in short stature. However, research should continue in these areas to define which children may benefit from GH treatment.     

Effect of growth hormone treatment in children with craniopharyngioma with reference to the KIGS (Kabi International Growth Study) database

In children with craniopharyngioma, poor growth commonly precedes diagnosis, but is observed less frequently than neurological or visual symptoms. A deficiency of growth hormone (GH) is common before, and almost universal after, treatment of the tumour, and is usually treated with GH. However, a minority of these children with GH deficiency (GHD) grow well without GH replacement therapy but exhibit other metabolic effects of GHD that are correctable by GH treatment. This article provides a review of studies in 422 children with craniopharyngioma whose details have been entered into the database of KIGS, the Kabi International Growth Study. The response to GH during the first year of therapy was similar to that seen in children with idiopathic GHD (IGHD). Leg length was relatively greater than sitting height and this disproportion was maintained during treatment. Adiposity increased in some children receiving GH treatment. At the end of GH treatment in 82 patients, there was a median gain in height SD score of 1.51, with evidence of residual growth potential still remaining in the majority. Tumour recurrence occurred in 13.5% of the total group of patients with craniopharyngioma within KIGS, at a median of 3.9 years from diagnosis and 2.3 years from the start of GH therapy. Tumour recurrence was not associated with an impairment in height achieved, but there was a tendency towards greater adiposity in patients in whom recurrence occurred. Adverse events during GH treatment were more frequent in children with craniopharyngioma than in those with IGHD, and headache was commonly reported. The results of these studies suggest that GH treatment is recommended for the treatment of children with craniopharyngioma on the grounds of improved growth velocity, adult height and other GH-dependent metabolic functions, and of the good safety profile of GH in these patients.     

Growth hormone improves growth rate and preserves renal function in Dent disease

Dent disease, an X-linked recessive renal tubular disease, results from loss-of-function mutations in the CLCN5 chloride channel gene. The effects of Dent disease on growth have not been described. We report siblings who presented with proteinuria, calciuria, and phosphaturia and growth failure who responded to growth hormone (GH) treatment. Genotyping revealed a novel c.2179delG frameshift mutation at codon 727, exon 12 of the CLCNS gene. Two years after initial presentation, linear growth had slowed, and evaluation revealed isolated GH deficiency. GH therapy resulted in more than two-fold increases in height velocity and serum IGF-I levels. There was no net change in estimated glomerular filtration rate, proteinuria or calciuria in response to GH therapy, but there was a delayed improvement in phosphaturia. These cases provide insight into the effects of GH on growth and renal function in Dent disease. Furthermore, we have reported a novel CLCN5 mutation.     

Growth hormone deficiency in a child with Williams-Beuren syndrome. The response to growth hormone therapy

Pre- and postnatal growth retardation of unknown pathogenesis is a common clinical feature in patients with Williams-Beuren syndrome (WBS). However, growth hormone deficiency (GHD) has not been considered a major cause of growth retardation. There is only one patient in the literature with confirmed GHD who responded well to human growth hormone (hGH) therapy. We report a female infant with confirmed WBS who, through provocative testing, was found to have GHD and who responded satisfactorily to hGH therapy. Height SDS was -4.2 at the age of 12 months when hGH was initiated and increased to -0.8 at the age of 4.25 years. The pathogenesis of GHD in our patient is unclear. Nevertheless, the elevated levels of prolactin and the response of hGH to growth hormone releasing hormone (GHRH) administration are indicative of a hypothalamic rather than pituitary defect. In conclusion, GH deficiency might contribute to the growth failure in a number of patients with WBS and in such cases hGH therapy will most likely improve final height.     

生长激素缺乏症与非酒精性脂肪肝

生长激素除了具有促进生长的作用外, 还对健康状态下的中间代谢有显著影响。但儿科医师通常关注于生长激素的促进生长作用, 而容易忽视对代谢的影响。近年来, 各种动物和人体（主要是成人）的研究以及儿童的临床报告一再表明生长激素缺乏症和脂肪肝之间存在联系。尽管目前尚缺乏涉及儿童的研究, 儿科临床医师应不仅确保生长激素缺乏症的患者得到适当的治疗, 而对于已经完成线性生长的青少年也应得到适当的过渡到成人的生长激素治疗。     

Management of Growth Hormone Deficiency Through Puberty

ABSTRACT. As a model of the growth hormone (GH) dependence of growth in prepuberty and puberty, the growth of 182 children (93 boys, 89 girls) who survived in first remission for treatment of acute lymphoblastic leukaemia was examined. Chemotherapy regimens, including intrathecal methotrexate, were similar in all patients, but CNS treatment differed, in that one group received 2400 cGy cranial irradiation, while the other received 1800 cGy. There was a significant decrease in height SDS during prepuberty, which was equivalent in both sexes, whereas there was a much greater decrease in pubertal growth in girls than in boys. Girls treated with the lower dose regimen of cranial irradiation had their onset of pubertal maturation significantly advanced, to a mean of 9.9 years ( p < 0.001). Previous studies have indicated that the duration of puberty is shortened by GH treatment in patients with idiopathic multiple pituitary hormone deficiency or isolated GH deficiency (GHD). To determine whether an increase in the dose of GH administered during the adolescent growth spurt would improve final height, a prospective randomized trial was performed in 32 children (25 boys, 7 girls) with isolated GHD treated with a GH dose regimen of 15 IU/m²/week as daily s.c. injections. At the onset of the pubertal growth spurt, the patients were randomized either to an unchanged dose or to 30 IU/m²/week. There was no significant change in height velocity with the doubled dose of GH, but there was a trend in the advancement of pubertal maturation which was considered to be dose related. It is suggested that these findings are of relevance to the treatment of GHD in puberty, especially in girls with early or precocious puberty occurring as a consequence of low-dose cranial irradiation. It is concluded that optimum final heights may not be achieved in these patients without the therapeutic manipulation of the onset and/or duration of puberty.     

No Improvement of Adult Height in Non-growth Hormone (GH) Deficient Short Children with GH Treatment

It is still in doubt whether the standard-dose growth hormone (GH) used in Japan (0.5 IU/kg/week, 0.167 mg/kg/week) for growth hormone deficiency is effective for achieving significant adult height improvement in non-growth hormone deficient (non-GHD) short children. We compared the growth of GH-treated non-GHD short children with that of untreated short children to examine the effect of standard-dose GH treatment on non-GHD short children. GH treatment with recombinant human growth hormone (rhGH) was started before the age of 11 yr in 64 boys and 76 girls with non-GHD short stature registered at the Foundation for Growth Science who have now reached their adult height. In 119 untreated boys and 127 untreated girls whose height standard deviation score (SDS) was below –2 SD at the age of 6 yr, height growth was followed until 17 yr. Height SDS was significantly lower before GH treatment in the GH-treated group than at the age of 6 yr in the untreated group, in both sexes. Adult height and adult height SDS were significantly greater in the untreated group than in the GH-treated group, in both sexes, although the change in height SDS did not differ significantly. Height SDS was significantly lower before GH treatment in the GH-treated group than at the age of 6 yr in the untreated group, so 57 boys and 57 girls whose height SDS at the age of 6 yr in the untreated group closely matched the height SDS before GH treatment in the GH-treated group were chosen for comparison. Height SDS did not differ significantly between the GH-treated group before GH treatment and the untreated group at the age of 6 yr, nor were there differences between these subgroups in adult height, adult height SDS, or height SDS change, in either sex. The effect of GH treatment is reported to be dose-dependent and doses over 0.23 mg/kg/week are reported to be necessary to improve adult height in non-GHD short children. Currently, the GH dose is fixed at 0.175 mg/kg/week in Japan, and we expected to find, and indeed concluded, that ordinary GH treatment in Japanese, non-GHD short children does not improve adult height.     

Growth hormone therapy in short stature

Unlimited availability of growth hormone (GH), and the demonstration of increased growth velocity (GV) during GH treatment in non-GH-deficient children have suggested new indications for GH therapy in short stature. There are two principle conditions with GH-related short stature: classical growth hormone deficiency (CGHD) and growth hormone neurosecretory dysfunction (GHND). Present knowledge about the effects of GH treatment in these and other disorders of short stature are reviewed. In non-CGHD, it is not possible to predict the short-term effect on growth during GH therapy, and even if GV increases, the effect on final adult height remains to be documented. This, together with potential side effects and the high expense of GH treatment, exhort to a restricted attitude towards routine GH treatment of short children without GH deficiency.     

Growth and adult height in atypical coeliac patients, with or without growth hormone deficiency

OBJECTIVE: To evaluate the effect of a gluten-free diet on growth and adult height, when available, in coeliac children without gastrointestinal symptoms. PATIENTS AND METHODS: Sixty-one coeliac children without gastro-intestinal symptoms were included in the study. The age at diagnosis was 9.50 +/- 3.3 years. Thirty-eight had short stature at diagnosis (< 10th percentile) and 23 had normal stature. Thirty-seven reached adult height. RESULTS: After beginning the diet an increase in growth velocity was seen in 30 patients (responders) (20 with initial short stature), while in 31 patients (18 with short stature) there was no catch-up growth (non-responders). Bone age at diagnosis was significantly more delayed in the responders than in the non-responders. Target height was significantly higher in children with normal stature at diagnosis than those with short stature. Growth hormone (GH) deficiency was found and confirmed after 6-12 months of diet in 12 of the 38 patients (32%) with short stature. In the group of the 30 'short' patients who attained final height, target height was attained or improved in 12 patients (40%): in eight of the 16 (50%) responders and in four of the 14 (29%) non-responders; in eight (all responders) out of 22 (36%) without GH deficiency, and in four out of eight (50%) patients with GH deficiency treated with GH (all non-responders). CONCLUSIONS: In children in whom coeliac disease is diagnosed because of short stature, a gluten-free diet will be successful if at diagnosis there is a delay of bone age and in the first year of diet there is an evident catch-up growth. When this does not occur, i.e. in half of the patients (18 out of 38), it may be because of an associated and transient GH deficiency. In these patients a period of GH replacement therapy as well as a gluten-free diet may improve their final height.     

Effect of growth hormone treatment on hypoglycemia in a patient with both hepatic glycogen synthase and isolated growth hormone deficiencies

A 7 year-old boy presenting with growth retardation, fasting hypoglycemia and ketoacidosis was diagnosed as having both idiopathic growth hormone (GH) deficiency and hepatic glycogen synthase (GS) deficiency caused by a homozygous mutation in exon 5 of the liver glycogen synthase gene (GYS-2). After four years of treatment with recombinant human GH, height increased from -4.9 SDS to -2.05 SDS which is near his target height of -1.6 SDS. The GH treatment, however, did not prevent the fasting hypoglycemia. Blood glucose levels were only normalized after avoiding fasting intervals of more than five hours and the frequent feeding of protein-rich meals according to the guidelines for treatment of hepatic GS deficiency.