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目的探讨血清生长激素(GH)、胰岛素样生长因子-1(IGF-1)及尿GH检测对矮小儿童诊断的意义。方法华中科技大学同济医院儿科于2004-11—2005-06对106例矮小儿童进行垂体功能复合刺激试验,试验前收集所有受试者夜间12h(2000~800)尿。另选取19例正常青春发育期前儿童为对照组。对垂体功能复合刺激试验GH分泌异常的56例矮小儿童,用ELISA方法检测相应的血清GH、IGF-1及尿中GH水平,并进行相关分析。结果根据垂体功能复合刺激试验的GH检测结果将矮小儿分类,包括完全性GH缺乏症(cGHD)25例、部分性GH缺乏症(pGHD)9例和GH神经分泌功能障碍(GHND)22例。GHD组患儿血清IGF-1、尿GH水平与正常儿相比明显降低(P<0·01)。pGHD和GHND组患儿血IGF-1水平波动较大,无统计学差异。GHND组患儿尿GH水平按ng/g肌酐(Cr)计量显著低于正常对照相(P<0·05),而按ng/12h尿量计算值虽低于正常组,但无统计学意义(P>0·05)。pGHD组患儿尿GH水平按两种方法计量值均介于正常和GHD患者之间,与正常及GHD患者比较均有显著性差异(P均<0·05)。cGHD和pGHD组患儿尿GH的ng/gCr计量值与其血GH峰值呈显著性正相关(rcGHD=0·556,P<0·05;rpGHD=0·423,P<0·05),GHND组患儿尿GH的ng/gCr计量值与其血中GH峰值无相关性(P>0·05)。结论尿GH水平测定无创、简便,配合IGF-1等指标的检测,对于矮小儿童的诊断和鉴别诊断具有重要意义。     

Age-Related Changes in Urinary Growth Hormone Level and Its Clinical Application

In order to establish the normal range of urinary growth hormone (GH) level for age and sex, which is important in the clinical application of urinary GH to diagnosis, we measured GH in the first morning urine specimens of 270 normal subjects aged 3 to 20 years. Urinary GH levels in patients wit documented GH deficiency were compared with those of the normal controls. In normal subjects, urinary GH levels showed a statistically significant change with age. They were relatively high in infancy and mid-puberty, reaching a peak at 11 to 12 years in girls and at 13 to 14 years in boys. Urinary GH levels in patients with complete GH deficiency were apparently lower (<-2.0SD) than those of the normal hildren, while the levels in patients withpartial GH deficiency overlapped with the normal range. When assessing GH secretion by using urinary GH measurement, consideration of age and sex is required, since the level changes isgnificantly wit these factors.     

Assay-Dependent Results of Immunoassayable Spontaneous 24-Hour Growth Hormone Secretion in Short Children

ABSTRACT. Forty-eight children, referred for evaluation of short stature, underwent 24-hour spontaneous growth hormone (GH) secretion studies. The GH level in pooled sera was assessed for each child, using up to 11 commercial immunoassays. In a group of 15 children, the mean GH values obtained by nine of the assays were compared with the mean value given by a polyclonal radioimmunoassay (RIA) from Sorin: four gave higher results ( p < 0.0001), three gave comparable results and two gave lower results ( p < 0.001). The assay yielding the highest results (Nichols: 5.9 ± 2.3 ng/ml, mean ± SD) gave values that were approximately triple those obtained by the assay yielding the lowest results (Hybritech: 1.8 ± 0.8 ng/ml; p < 0.0001); both of these are monoclonal immunoradiometric assays (IRMAs). The GH concentrations measured in 24-hour pools from 32 children using a monoclonal IRMA from Biomerieux were similar to those obtained using a polyclonal RIA from Farmos (2.8 ± 1.1 ng/ml and 2.9 ± 1.4 ng/ml, respectively) but significantly lower than those measured by another polyclonal RIA from Sorin (3.5 ±1.5 ng/ml). Two polyclonal assays (Biomérieux and Sorin) were then used to measure the GH levels in all of the 30-minute samples and in the day, night and 24-hour pools from the secretion studies of 22 children. The ratio of the results of the two assays remained fairly constant for a given child (although the GH levels in different 30-minute samples differed considerably). However, the ratios between different children showed quite wide variation (from 2.03 to 1.04). It was concluded that the GH assay must be taken into account when evaluating data from GH secretion studies, and the disparity in the GH level measured by two or more assays may differ from child to child.     

Growth Hormone Treatment in Non-Growth Hormone-Deficient Children: Effects of Stopping Treatment

ABSTRACT. Overnight physiological growth hormone (GH) secretion was evaluated in 95 short, prepubertal children (73 boys, 22 girls). All the children were below the 3rd centile for height and achieved CH levels greater than 15 mU/1 following pharmacological stimulation. The mean average GH level was 7.1 mU/l and the mean sum of pulse amplitudes 80.4 mU/l. No relationship was found between age, height or height velocity and any of the parameters of GH secretion. The group was randomized to receive placebo, GH or remain under observation for the first 6 months and then all patients received GH treatment for a further 6 months. Those treated with GH, 0.27 IU/kg (0.1 mg/kg) three times weekly, in the first phase. demonstrated a mean increase in height velocity SDS of 3.24. There was no difference in growth response between the placebo or observation groups. In the second 6-month period. all children received GH according to the same dose regimen: they were then observed for a further 6 months following its discontinuation. In the 6 months following withdrawal of GH, all groups showed a significant fall in height velocity SDS, which returned to pretreatment levels, without demonstrating'catch-down'growth. Repeat sampling of overnight GH secretion within 3 days of discontinuing GH showed normal secretory patterns with a small reduction in mean peak amplitude. These results suggest that short children without classic GH insufficiency respond well to exogenous GH in the short term and return to pretreatment height velocities afterwards. Consequently, it may be possible to increase final adult height in such children by GH treatment.     

Growth hormone (GH) profiles in response to continuous subcutaneous infusion of GH-releasing hormone(1— 29)-NH2 in children with GH deficiency

Six children presenting with partial growth hormone (GH) deficiency (mean GH peak in two different tests, 8.0 k1.3 μ g/l ) aged 8–10.3 years (mean, 2.7 ± 0.9 years) were treated for 6 months by continuous subcutaneous infusion of GH-releasing hormone(1–29)-NH, (GHRH(1–29)-NH₂); 24-hour GH profiles and height velocity were measured. A biphasic effect of GHRH(1–29)-NH₂ infusion was observed. After an early substantial increase in the 24-hour integrated concentration of GH, from 1.6 ± 0.1 to 3.5 ± 0.7 μg/l/minute, a subsequent consistent decrease occurred by 3 months, which was more pronounced after 6 months (mean 24-hour integrated concentration of GH, 1.9± 0.9 μg/l/minute). This effect reflects modification of both pulse amplitude and frequency of GH secretion. At the end of the study, one child had complete suppression of GH secretion and two others showed only one peak above 5 μg/1 during a 24-hour period. No correlation was found between these changes and height velocity. Three children did not grow significantly; the other three children who had a growth response to GHRH(1–29)-NH₂ were those with the lowest 24-hour integrated GH concentration at the end of the study. The possible mechanisms involved in this biphasic effect, including GHRH antibodies, changes in somatostatin levels and/or desensitization of pituitary GHRH receptors, have been investigated.     

Growth Hormone Response to Growth Hormone-Releasing Hormone (hp GHRH-1-44) as an Index of Growth Hormone Secretory Dysfunction after Prophylactic Cranial Irradiation for Acute Lymphoblastic Leukemia (24 Grays)

ABSTRACT. The growth hormone response to growth hormone releasing hormone hp GHRH_1-14 (2 μg/kg i.v.) was studied in 19 prepubertal children who had been irradiated with 24 Gy for acute lymphoblastic leukemia (ALL) or lymphosarcoma (LS) at a mean chronological age of 410/12 years (limits 10/12 to 9 years). They were evaluated after a mean time interval of 4 8/12±3/12 years and compared to 14 prepubertal children with constitutional short stature (CSS). The individual responses to GHRH were decreased in all but three of the irradiated children. The mean GH response was 16.7±2.5 ng/ml as compared to 52.6±8.5 ng/ml in the control group ( p <0.001). The GH response to GHRH was not correlated with the GH response to arginine-insulin tolerance test (AITT). A decreased response to GHRH with values between 12.5 and 19.4 ng/ml was observed in four cases with normal growth rates and normal GH responses to AITT. These results suggest that an impaired GH response to GHRH is a frequent finding after cranial irradiation for ALL or LS and may be the only sign of GH secretory dysfunction. It is probably indicative of early hypothalamic impairment of GH secretion.     

Diagnostic significance of urinary growth hormone measurements in children with growth failure: correlation between serum and urine growth hormone

Twelve-h overnight urine and serum samples obtained simultaneously at 20-min intervals were assayed for growth hormone (GH). Ninety-one children, 5 to 16 y (Tanner stage 1 to 3) participated; group 1 were healthy children, group 2 were children with organic GH deficiency, and group 3 had idiopathic growth failure and normal GH stimulation tests. Serum pool GH concentrations in group 1 were similar to those in group 3 (3.3 +/- 0.3 versus 3.4 +/- 0.2 micrograms/L); group 2 had significantly lower GH concentrations (1.6 +/- 0.2 micrograms/L). Plasma IGF-I levels were significantly greater in groups 1 (14.2 +/- 2.6 nmol/L, p less than 0.001) than in groups 2 and 3 (2.6 +/- 0.5 and 5.5 +/- 0.7 nmol/L, respectively). Urinary GH (mean +/- SEM) standardized for body weight (micrograms/kg) in group 1 (0.31 +/- 0.02) was significantly greater than in group 2 (0.14 +/- 0.01) and group 3 (0.20 +/- 0.01). However, when expressed as microgram/mol creatinine, the output of GH was similar in group 1 (4.0 +/- 0.3) and group 3 (3.4 +/- 0.3); both groups had significantly greater output compared to group 2 (1.3 +/- 0.2). Urinary IGF-I (nmol/kg) in group 1 (0.22 +/- 0.02) was significantly greater than in group 2 (0.12 +/- 0.01) or group 3 (0.07 +/- 0.01). Urinary GH correlated with serum pool GH concentration (r = 0.64, p less than 0.001). Although urinary GH output reflects endogenous GH secretion, the overlap between groups 1 and 3 precludes using urinary GH measurements as a diagnostic test for GH deficiency in children with idiopathic growth failure.     

Microalbuminuria in Diabetic Children and Adolescents

ABSTRACT. Urinary albumin excretion (UAE) was determined by radioimmunoassay in two 24 h urine collections from 125 diabetic children and adolescents and from 71 normal children matched for age and sex. Thirteen patients (10.4%) aged > 12 years had microalbuminuria, i. e. log transformed UAE levels above the upper normal range (24.5 mg/24 h). UAE values were positively correlated with age, GH secretion, but not with duration of disease, glycosylated hemoglobin, renal size or N-acetyl-beta-glucosaminidase excretion. Diabetic normoalbuminuric children aged 10 years and older had significantly higher UAE than controls and than younger diabetic patients matched for duration of disease. HLA DR3/DR4 heterozygosity frequency was significantly higher (p<0.01) in the microalbuminurine group than in the normoalbuminuric. All microalbuminuric subjects (n=8) with short duration of disease (3.92 ± 3.43 yr) developed diabetes at puberty. In conclusion, our cross-sectional study suggests: if a number of factors are combined, i. e. HLA DR3/DR4 heterozygosity, onset of disease at puberty and higher GH values, the probability of developing abnormal levels of UAE will increase.     

Screening for growth hormone deficiency using urinary growth hormone measurement

The diagnostic approach in growth hormone deficiency (GHD) is complicated. Two or more provocative tests are essential for definitive diagnosis of GHD. However, such testing cannot be carried out routinely on all subjects with short stature because of the need for hospitalization and blood sampling. A simple screening method for GHD would be of great value. Human growth hormone (hGH) levels were measured in the early morning urine of 192 children aged 7–15 years with height 2.0 s.d. below the mean for their ages. Sixty-eight subjects were selected because they showed a urinary hGH level < 10 ng/g creatinine. They were further examined in terms of bone age and plasma insulin-like growth factor (IGF-I) levels. In 30 subjects, the ratio of bone age: chronological age was < 0.8 and/or plasma IGF-I level was < 0.7 U/mL. Finally 24 of these subjects were examined with provocative tests and other endocrinological tests. Eleven subjects proved to have poor growth hormone secretion and one subject was diagnosed as having Turner syndrome. In conclusion, 11 patients with GHD were diagnosed from 192 children with short stature using urinary hGH measurement as the first screening method. These findings suggests that urinary hGH measurement could be a useful and simple method for detecting GHD.     

Urine Growth Hormone Determinations Compared with Other Methods in the Assessment of Growth Hormone Secretion

Okuno, A., Yano, K., Itoh, Y., Hashida, S., Ishikawa, E., Mohri, Z-I. and Murakami, M. (Department of Paediatrics, Asahikawa Medical College, Hokkaido; Medical College of Miyazaki, Kiyotake, Miyazaki; and Research and Development Division, Sumitomo Pharmaceuticals Co Ltd, Hyogo, Japan). Urine growth hormone determinations compared with other methods in the assessment of growth hormone secretion. Acta Paediatr Scand [Suppl] 337:74, 1987.
Urinary excretion of hGH was studied in children with short stature using a sensitive sandwich enzyme immunoassay technique. Urinary hGH excretion, in terms of hGH: creatinine ratio, showed excellent correlation with the mean and peak hGH values during physiological and pharmacological tests. It seems that the urinary hGH levels reflect serum hGH profiles during the urine collection period. A border zone for the lower limits of normal hGH levels in the urine was 7.5–13.4 ng/g creatinine for the physiological test at night (from 2000 hours to 0600 hours) and 17.4–35.0 ng/g creatinine for the pharmacological tests. Assessment of hGH secretory status by the urinary hGH levels showed good agreement with the serum hGH response. Measurement of urinary hGH could be used as a diagnostic test for impaired hGH secretion, and the multiple blood drawing required in physiological and pharmacological tests might be replaced by urine sampling.     

Impaired Response of Growth Hormone-Releasing Hormone (GHRH) Measured in Plasma after L-Dopa Stimulation in Patients with Idiopathic Delayed Puberty

ABSTRACT. In order to investigate the regulation of GH secretion in patients with idiopathic delayed puberty (IDP), either prepubertal (stage P1) or early pubertal (P2), GHRH levels in plasma were measured after stimulation with L-Dopa in a group of 16 patients with IDP. The results were compared to those obtained in 12 patients with constitutional short stature (CSS) at the same stages of puberty, who underwent L-Dopa test for insufficient height. Plasma GHRH levels were measured, after extraction and concentration on C18 Sep Pack columns, by radioimmunoassay using an antibody against 1–40 GHRH, which cross-reacts 100% with 1–44 GHRH. The sensitivity of the assay is 6–8 pg/ml. After L-Dopa intake, the peak of GH was mean ± SEM 8.6±1.4 ng/ml in IDP and 12.0±0.8 ng/ml in CSS (NS). The peak of GHRH after L-Dopa was 41±10 pg/ml in IDP and 96±25 pg/ml in CSS ( p <0.02). A significant ( p <0.02) decrease of plasma GHRH peak values (mean ±SEM 17.3±4.4 pg/ml) was noted in the five patients with IDP whose growth velocity was below -2 SD for their bone age compared to the patients with normal growth velocity (mean ± SEM 75.0±14.5 pg/ml). These results suggest a hypothalamic dysfunction in patients with IDP, and a relationship between the well-known partial and transitory somatotropic deficiency found in some adolescents having a pubertal delay and their secretion of the releasing hormone GHRH.     

Role of Counterregulatory Hormones for Glucose Metabolism in Children and Adolescents with Type 1 Diabetes

To elucidate the mechanism of insulin resistance due to insulin counterregulatory hormones (ICRHs) and evaluate ICRH secretion kinetics, ICRH concentrations were measured and correlated with blood glucose levels in 28 type 1 diabetic patients. Blood glucose was measured before bedtime. Early morning urine samples were collected the next morning before insulin injection and breakfast. Fasting blood glucose, cortisol, glucagon and HbA1c levels were measured. Growth hormone (GH), adrenaline, cortisol and C-peptide levels in morning urine samples were measured; SD scores were calculated for urine GH. The laboratory values (mean ± SD) were as follows; HbA1c of 8.1% ± 1.4%; pre-bedtime glucose of 203 ± 105 mg/dl; fasting blood glucose of 145 ± 87 mg/dl; serum cortisol of 21.6 ± 5.5 µg/dl; plasma glucagon of 98 ± 41 pg/ml; urinary GH, 27.2 ± 13.0 ng/gCr; urinary cortisol of 238 ± 197 ng/gCr; and urinary Adrenaline of 22.9 ± 21.0 ng/gCr. The mean urinary GH SD score was increased (+1.01 ± 0.70; p=0.000); the mean plasma glucagon lebel (98 ± 41 pg/ml) was not. Fasting blood glucose was positively correlated with plasma glucagon (R=0.378, p=0.0471) and negatively correlated with urinary cortisol (R=–0.476, p=0.010). Urinary adrenaline correlated positively with urinary GH (R=0.470, p=0.013) and urinary cortisol (R=0.522, p=0.004). In type 1 diabetes, GH, glucagon and cortisol hypersecretion may contribute to insulin resistance, but the mechanism remains unclear.     

Effects of Short-Term Growth Hormone Therapy in Short Children without Growth Hormone Deficiency

ABSTRACT. Evaluation of 24-hour endogenous growth hormone (GH) secretion was carried out in 62 children, aged 7-16 years, who did not have classic GH deficiency (GHD). The mean 24-hour GH concentration, determined at 20-minute intervals over 24 hours, was variable, ranging from 1.28 to 11.39 μg/l with a mean of 4.95 ± 2.55 μl (± SD). There was a positive correlation between mean 24-hour GH concentration and plasma insulin-like growth factor I (IGF-I) values ( r = 0.54; p < 0.01). Recombinant human GH, 0.1 IU/kg/day was administered to 30 of the 62 children for 6 months followed by 6 months'observation without treatment. Thereafter, GH was administered at the same dose for a further 6 months to 16 children. The mean height velocities before, during, and after the first treatment period were 4.3 ± 0.9, 7.3 ± 1.9 and 4.9 ± 2.0 cm/year (mean ± SD), respectively. The height velocity during treatment was greater than pre- and post-treatment values ( p < 0.001). The height velocity Increased again during the second treatment period to a mean of 8.5 ± 2.0 cm/year ( p < 0.001). Nine other children were treated continuously in a similar manner for 1 year and their height velocity increased significantly from 4.1 ± 1.4 to 6.0 ± 1.9 cm/year ( p < 0.001). According to our criteria, 29 of the 39 children (74.4%) who were treated for 6-12 months showed a GH-dependent height increase during therapy. There were no differences between the children who responded to GH treatment and those who did not in terms of Chronological age, bone age, plasma IGF-I level, maximal GH level to insulin-induced hypoglycaemia, or mean 24-hour plasma GH concentration. These data indicate that some short children without GHD respond to GH treatment with an increased height velocity. Further investigations are required to determine the effect of GH on final height.     

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.     

Circadian growth hormone secretion in short multitransfused prepubertal children with thalassaemia major

Growth hormone (GH) secretion was determined by evaluating circadian GH profiles for 24 h and GH responses to clonidine stimulation test and insulin-stimulated hypoglycaemia (ITT), in nine prepubertal children with -thalassaemia major (TM) and 17 with non-GH deficient short stature (NGHDSS). The TM children were multitransfused and had early and intensive chelation therapy. All patients had normal hypoglycaemia to ITT, with peak GH levels of 15.71±5.86 ng/ml for children with NGHDSS and 13.91±7.20 ng/ml for children with TM. Peak GH levels during a clonidine test were 17.54±5.30 and 17.15±1.38 ng/ml, respectively. The GH peak parameters such as the number of peaks, the integrated GH concentration and the area under the curve (AUC) were similar in both groups of children and reflected the total 24-h secretion and the daily and nocturnal secretion separately. An abnormal 24-h GH profile compatible with the diagnosis of endogenous neurosecretory GH dysfunction was found in only two out of nine children with TM and in four out of seven children with NGHDSS.Conclusion Our data suggest that growth hormone neurosecretory dysfunction is not a universal finding in children with thalassaemia major but might depend on the degree of iron deposit in the pituitary.     

A cross-sectional study of growth, puberty and endocrine function in patients with thalassaemia major in Hong Kong

Methodology: A cross-sectional study of growth, puberty and endocrine function was performed on 35 girls and 33 boys with thalassaemia major.
Results Despite regular transfusion and chelation therapy, 75% of the girls and 62% of the boys over the age of 12 years were below the third percentile for height. Hypogonadotropic hypogonadism was found in a similar percentage of patients. Moderate to marked zinc deficiency secondary to chelation therapy was considered unlikely because normal serum zinc levels were found in all but three of our patients, but we could not exclude the possibility of a marginal status of zinc nutrition causing growth failure. Growth hormone deficiency and diabetes mellitus were sometimes encountered but hypothyroidism, hypoparathyroidism and adrenal insufficiency were rare among our patients. Most of the patients with growth failure had normal growth hormone (GH) response to insulin induced hypoglycaemia. The serum insulin-like growth factor-1 (IGF-1) levels were low in our patients and no significant difference in the serum IGF-1 levels was found between prepubertal children with or without growth failure (0.4±0.1 mU/mL vs 0.37±0.11 mU/mL, P = 0.39). Similarly, no difference in the serum IGF-1 levels was found between pubertal children with or without growth failure (0.48 ± 0.2 U/mL vs 0.56 ±0.14 U/mL, P= 0.26).
Conclusions Delayed sexual maturation and a possible defect in growth unrelated to the GH-IGF-1 axis may be responsible for the growth failure in adolescent children with thalassaemia major.     

Physiological Growth Hormone Secretion and Response to Growth Hormone Treatment in Children with Short Stature and Intrauterine Growth Retardation

Stanhope, R., Ackland, F., Hamill, G., Clayton, J., Jones, J. and Preece, M.A. (Department of Growth and Development, Institute of Child Health, London and Serono Laboratories, UK). Physiological growth hormone secretion and response to growth hormone treatment in children with short stature and intrauterine growth retardation. Acta Paediatr Scand [Suppl] 349: 47, 1989.
Physiological growth hormone (GH) secretion was examined in 31 children (8 girls, 23 boys) with short stature secondary to intrauterine growth retardation (IUGR). Seventeen (4 girls, 13 boys) had dysmorphic features of Russell-Silver syndrome. Four of the 31 children had GH insufficiency with peak GH levels of < 20 mU/I during the night. Nine of the patients (8 of whom had Russell-Silver syndrome) had a single nocturnal GH pulse. Twenty-three children (6 girls, 17 boys) were randomized into two groups treated with either 15 or 30 U/m²/week of GH by daily subcutaneous injections. Age, sex distribution, pretreatment height velocity SD score (SDS), and distribution of dysmorphic and non-dysmorphic children were similar in both groups. The group treated with 15 U/m2/week for a mean of 0.82 years showed an increase in mean height velocity SDS from - 0.61 to +1.09, and the group treated with 30 U/m²/week for a mean of 0.92 years showed an increase in mean height velocity SDS from -0.69 to +3.48. The results suggest that physiological GH insufficiency is probably common in children with Russell-Silver syndrome and that both dysmorphic and non-dysmorphic children with short stature secondary to IUGR will respond to GH treatment. Initial evidence suggests that the increase in short-term growth velocity does not result in an improved final height prognosis.     

Somatostatin infusion withdrawal in the diagnosis of childhood growth hormone deficiency

OBJECTIVE: An evaluation of growth hormone (GH) testing for GH deficiency (GHD) in childhood is confounded by the lack of a world-wide consensus on the definition of GHD. Although a single GH test remains the most powerful biochemical tool in the evaluation of a child with growth failure, the test remains far from ideal. Withdrawal of somatostatin (SS) infusion is followed by a rebound rise of GH thought to be mediated by endogenous GH-releasing hormone (GHRH) function. This study was designed to compare the GH response to 90 min SS infusion in children with normal GH secretion versus children with GH deficiency. METHODS: Ten children with GHD and 10 healthy controls (NC) have been evaluated for GH response to somatostatin infusion withdrawal (SSIW) and compared with response of two provocative tests, glucagon plus propranolol test and L-Dopa test. All children received constant infusion of somatostatin for 90 min (3 microg/kg per h, Stilamin, Serono, Aubonne, Switzerland). In order to determine GH, blood samples were obtained 90 min before the SS infusion and 0, 15, 30, 45, 60, 75, and 90 min after the cessation of infusion. RESULTS: Growth hormone peak levels with SSIW were significantly lower in GH deficient children than in healthy children (2.5 +/- 1.2 ng/dL, vs 21.9 +/- 5.3 ng/dL, respectively, P < 0.01). No adverse effects were observed during or after somatostatin infusion. CONCLUSION: In the present study, SSIW elicited a significant GH rise in healthy children but not in children with GH deficiency. Although further controlled studies using more data are necessary to expand these findings, the results suggested that children with GH deficiency can be reliably discriminated from healthy children by SSIW.     

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.     

Adult height after cranial irradiation with 24 Gy: factors and markers of height loss

The decrease in adult height of children who have been given cranial irradiation (24 Gy) for acute lymphoblastic leukaemia is attributed to chemotherapy, growth hormone (GH) deficiency and early puberty. This study evaluates the factors involved in the height loss between irradiation and adult height and its markers in 43 patients irradiated at 5.8 ± 0.4 (SEM) years. The mean height loss was 0.9 ± 0.2 SD in the children with a normal GH peak ( n = 11), 1.7 ± 0.2 SD in those with a low GH peak and untreated ( n = 15) and 0.6 ± 0.2 SD in those treated with GH ( n = 17). The adult height was significantly lower than target height in all three groups. The height loss correlated negatively with the GH peak ( p < 0.02) and with the age at onset of puberty ( p < 0.05) in the first two groups with spontaneous growth, but not with the chemotherapy regimen or its duration, or the plasma insulin-like growth factor I (IGFI) and its GH-dependent binding protein (BP-3). Early puberty (onset at 8-10 years) occurred in 6 girls from the first two groups. At the first evaluation, 5.6 ± 0.4 years after irradiation, the GH peak values after arginine-insulin stimulation correlated with the age at irradiation ( p < 0.03), taking into account the time since irradiation. The plasma 1GF1 and BP-3 values were correlated with each other, but not with the GH peak. In conclusion, this study demonstrates the impact of GH deficiency and GH replacement therapy on adult height in children given cranial irradiation for leukaemia. They therefore should be evaluated for their GH secretion 1 2 years after the end of chemotherapy. GH therapy is indicated for those with low GH peak and decreased growth rate or no increase in growth rate despite puberty.