IGF-I及IGFBP-3对生长激素缺乏症患儿诊断及疗效判断的价值

为了探求一次性抽血确诊生长激素缺乏症 (GHD)的方法和寻找一个检测GH治疗效果的可靠而敏感的生化指标 ,分别用RIA法和IRMA法检测25例GHD患儿血清胰岛素样生长因子 -I(IGF -I)、胰岛素样生长因子结合蛋白 -3(IGFBP -3) ,同时进行生长激素 (GH)刺激试验 ;将GHD患儿分为2组 ,完全性缺乏组 (cGHD)及部分缺乏组 (pGHD) ,将2组血清IGF -I、IGFBP -3与年龄、性别配对的正常儿童 (C组 )均值对照 ,并对照不同年龄及不同发育期的50例正常儿童参考范围 ,计算GHD患儿血清IGF -I、IGFBP -3的降低率 ;将IGF -I与GH峰值做相关性分析。用rhGH治疗GHD3个月后将IGF -I增高值 (△IGF -I)与治疗后每年生长速度 (GV)做相关性分析。结果显示 ,GHD组血清IGF -I、IGFBP -3均显著低于正常对照组 ,两组无重叠 ,cGHD组与pGHD组比较 ,两者差异显著 ;IGF -I及IGFBP -3在GHD组及C组均呈显著正相关 ;GHD组血清IGF -I与GH峰值呈显著正相关 (r=0.85,P<0.001) ,回归方程 :y=0.1613 +0.0235x ,由此可根据血清IGF -I测定值求出GH峰值 ;治疗3个月后△IGF -I与治疗后GV呈显著正相关。提示IGF -I、IGFBP -3对GHD患儿的诊断有重要价值 ;GH峰值可根据所测IGF -I由回归方程求出 ,以代替传统的生长激素刺激试验 ;IGF—I是判断rhGH治疗效果的可靠而     

小剂量司坦唑醇对非生长激素缺乏症矮小儿童促生长疗效观察

司坦唑醇(stanazolol，ST)即吡唑甲氢龙，又称康力龙，是临床常用于促生长的蛋白同化类固醇激素(AAS)之一。ST有良好的促生长作用，但同时也促进骨龄(BA)成熟。近年发现，用小量ST可避免BA加速的不良作用。我们通过观察小剂量ST对非生长激素缺乏症(NGHD)矮小儿童生长速度及BA的影响，探讨ST对NGHD患儿的疗效。     

从循证医学证据看生长激素促生长治疗的收益及风险

基因重组人生长激素（rhGH）自1985年上市以来,已经治疗了上百万矮身材患儿,适应证不断扩大。同时,超适应证用药及单纯为增高而用药的现象也越来越严重。为此,多个学术组织出台指南或共识期望规范rhGH的诊疗。rhGH治疗生长激素缺乏症（growth hormone deficiency,GHD）终身高获益最大,其他非GHD疾病包括特发性矮小、特纳综合征等应用rhGH促生长收益有限。rhGH长期应用的安全性尚存有争议,临床医生处方rhGH时应谨慎,做到规范化使用。     

重组人生长激素治疗特发性矮小儿童12例

目的　观察重组人生长激素 (rhGH)治疗特发性矮小儿童促生长作用。方法　对 12例特发性矮小儿童使用rhGH治疗 0 .5 7± 0 .18年 ,比较治疗前后年生长速率和预测成年身高结果。结果　经治疗后特发性矮小儿童的年生长速率和预测成年身高有显著提高 ,身高年龄增长明显快于生活年龄和骨龄的增长。结论　rhGH对特发性矮小儿童具有促生长作用     

31例生长激素缺乏症患儿生长激素释放激素激发试验结果分析

对31例生长激素(GH)缺乏症患儿进行了生长激素释放激素(GHRH)激发试验,发现14例(45.2%)在注射GHRH后15～60分钟GH峰值显著升高(>10ng/ml),峰值范围14.93～42.27ng/ml,平均24.58ng/ml,表明此类患儿系因下丘脑缺乏GHRH所致。身高在均数-3SD以下和具有典型GH缺乏症面容和体态者,GHRH缺乏组均明显少于垂体性GH缺乏组(P均<0.01),提示对一些临床表现不典型的身材矮小患儿应疑及下丘脑性GHRH缺乏。     

重组人生长激素治疗生长激素缺乏症患儿影响生长速度疗效的因素

自1993年10月我们开始采用基因重组人生长激素（rhGH）治疗生长激素缺乏症（GHD）患儿,部分患儿疗程达7年半。现将治疗半年以上的患儿生长发育情况总结如下。     

特发性矮小患儿生长激素受体基因Ex3多态性与重组人生长激素疗效分析

目的：观察生长激素受体（GHR）基因Ex3多态性与重组人生长激素（rhGH）治疗青春期前特发性矮小（ISS）疗效间的相关性。方法：青春期前ISS患儿30例,均采用rhGH［0.116±0.02 IU/(kg/d)］治疗;其外周血白细胞中抽提基因组DNA,采用多重PCR扩增GHR基因Ex3区域。对不同基因型患儿治疗后生长速率（GV）、年龄对应身高标准差积分（HtSDSCA）及骨龄对应身高标准差积分（HtSDSBA）、预测终身高进行比较。结果：rhGH治疗半年后d3/d3基因型组GV较fl/fl基因型组明显增加［（6.3±1.6）cm/年 vs （3.4±0.5）cm/年,P<0.05］。结论：ISS患儿GHR Ex3基因型与rhGH促生长疗效存在一定关联,d3/d3等位基因型患儿用rhGH治疗后生长速率明显优于fl/fl等位基因型。［中国当代儿科杂志,2010,12（9）：730-733］     

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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。     

重组人生长激素治疗不同生长激素分泌状态青春前期矮身材患儿近期疗预测模型的建立和验证

目的 建立重组人生长激素(rhGH)治疗生长激素不同分泌状态青春前期矮身材患儿近期(1年)疗效的预测模型,并进行初步验证.方法回顾性分析62例生长激素不同分泌状态的青春前期矮身材患儿[模型组,分为全模型组(模型组全部病例)和生长激素缺乏症模型组(模型组中生长激素缺乏症的病例)]经rhGH治疗1年后的追赶性生长指标:生长速度(HV)和身高Z分增值(ΔHtSDS).根据单因素相关分析的结果,通过多元回归的方法,分别建立对HV和ΔHtSDS的2个预测方程(Model-GHD和Model-total).前瞻性分析另14例(验证组),将资料代入前述方程进行验证.结果单因素相关分析显示,与HV和ΔHtSDS显著(负)相关的是同一组影响因素.所得4个预测方程,R2在0.244～0.519,P值均＜0.05.HV的2个预测方程和对生长激素缺乏症患儿1ΔHtSDS的预测方程(实测值和预测值呈显著正相关,r在0.753～0.996;配对t检验示两者差异无统计学意义).结论预测模型建立成功,有助于预测不同生长激素分泌状态青春期矮身材患儿的生长激素的近期疗效.     

重组人生长激素治疗生长激素缺乏症疗效观察

目的 观察基因重组人生长激素(rhGH)对生长激素缺乏症(GHD)患儿的疗效。方法 对15例GHD患儿应用rhGH治疗,每晚睡前皮下注射0.1 IU/kg,疗程6个月。结果 患儿身高由治疗前109.3±9.9cm增加到115.5±11.3 cm;年身高生长速度由治疗前2.8±0.6cm/年增加到11.6±3.5cm/年。治疗期间除少数患儿出现亚临床甲状腺功能低下,注射部位有轻度反应外,未发现明显副作用。结论 皮下注射rhGH是治疗儿童GHD的一种安全有效的方法。     

Growth Response to Human Growth Hormone Treatment in Children with Partial and Total Growth Hormone Deficiency

ABSTRACT. The growth response during the first and second years of human growth hormone (hGH) treatment was studied in 14 prepubertal children with so-called "partial" GH deficiency (peak GH between 8 and 15 mU/1) and compared to 28 prepubertal children with "total" GH deficiency (peak GH less than 8 mU/1). There was no difference in growth acceleration between children with partial and total GH deficiency, when initial covariables were taken into account. In a stepwise multiple regression analysis initial stature, pre-treatment growth velocity and skinfold thickness were shown to be most related to growth response, but after exclusion of 3 children with a genetic form of total GH deficiency and partial TSH deficiency this relationship was lost. GH levels during provocation tests and auxological criteria have a poor predictive value for growth response to hGH therapy.     

Oral administration of arginine enhances the growth hormone response to growth hormone releasing hormone in short children

We have evaluated the effect of oral administration of arginine chlorhydrate on the growth hormone response to growth hormone releasing hormone in a group of nine short prepubertal children (six boys and four girls). Arginine chlorhydrate 10 g, administered orally 60 min before an iv bolus injection of growth hormone releasing hormone 1–29, 1 μg/kg, significantly enhanced the growth hormone response to the neuropeptidc, confirming the results of previous studies which used the iv route. Furthermore, our data strengthen the view that the effects of arginine chlorhydrate on growth hormone secretion are mediated by inhibition of endogenous somatostatin release.     

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??Objective??To describe height velocity in pre-pubertal Growth Hormone Deficiency??GHD?? children without recombinant human growth hormone??rhGH?? treatment and explore the height velocity targets for the first year in response to rhGH treatment. Methods??Analyze retrospectively the height velocity data without??HV0?? and one year after ??HV1?? rhGH treatment in physiologic dose??0.7 U/??kg·w???? in pre-pubertal GHD children above 3 years old who were diagnosed from Jan??2000 to Dec??2009 in our hospital. The GHD patients who were included for calculation of HV0 had peak GH value in GH provocative test less than 7 ng/ml. HV0 was calculated according to age??HV0-CA??342 patients?? and bone age??HV0-BA??257 patients?? respectively. According to the peak GH value in GH provocative test??the patients who were included for calculation of HV1 were divided into GHD-1 group????0.33 nmol/L??140 patients?? and GHD-2 group??7.0??9.9 μg/L??33 patients??. Results??Within every bone age group??GHD-1 group had significantly higher HV1 than GHD-2 group??P??0.05????11.0??10.5-11.5?? cm/a??n??34?? vs. 9.9??9.1-10.8?? cm/a??n??6?? when bone age was less than 3 years??10.4??9.8-10.9?? cm/a??n??48?? vs. 8.8??8.3??9.2?? cm/a??n??8?? when bone age was between 3 to 5 years??and 9.5??9.1-9.9?? cm/a??n??58?? vs. 8.5??8.0-9.1?? cm/a??n??19?? when bone age was between 6 to 10 years. The mean HV1 of GHD-2 was very close to the 25th percentile??P25?? of GHD-1 group. They both were significantly higher than HV0-BA. Conclusion??The recommended height velocity target for the first year after rhGH treatment in pre-
pubertal GHD children is the P25 of HV1 of GHD-1 group. It should be at least 9.9 cm/a??8.7 cm/a and 8.3 cm/a when the bone age is less than 3 years??3 to 5 years and 6 to 10 years?? respectively.     

Oral administration of arginine enhances the growth hormone response to growth hormone releasing hormone in short children

We have evaluated the effect of oral administration of arginine chlorhydrate on the growth hormone response to growth hormone releasing hormone in a group of nine short prepubertal children (six boys and four girls). Arginine chlorhydrate 10 g, administered orally 60 min before an iv bolus injection of growth hormone releasing hormone 1–29, 1 μg/kg, significantly enhanced the growth hormone response to the neuropeptidc, confirming the results of previous studies which used the iv route. Furthermore, our data strengthen the view that the effects of arginine chlorhydrate on growth hormone secretion are mediated by inhibition of endogenous somatostatin release.     

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.     

Investigation of Growth Hormone Secretion in Patients with Intrauterine Growth Retardation

Rochiccioli, P., Tauher, M., Moisan, V. and Pienkowski C. (Department of Paediatrics, CHU Rangneil, Toulonse Cedex, France). Investigations of growth hormone secretion in patients with intrauterine growth retardation. Acta Paediatr Scand [Suppl] 349: 42, 1989.
Growth hormone (GH) deficiencies have rarely been reported in intrauterine growth retardation (IUGR). This study has investigated GH secretion using GH provocation tests, 24-hour GH secretory profiles, and insulin-like growth factor I (IGF-I) measurements in 24 children with intrauterine growth retardation. The criteria for diagnosis were a birth length and weight below the 10th percentile for gestational age. The average age at investigation was 5.5 years, and the average growth retardation was -3.3 SD. Twenty children had shown catch-up growth between the ages of 6 months and 3 years, followed by varying decreases in growth velocity. Studies of GH secretion demonstrated GH deficiency in 16 patients, with neurosecretory dysfunction in six. Treatment with pituitary GH in nine children increased mean growth velocity from 3.5 cm/year to 7 cm/year. GH therapy should thus be effective in improving the height prognosis of children with intrauterine growth retardation.     

Growth hormone therapy for 3 years: The OZGROW experience

Objective : To examine the growth response over 3 years of growth hormone deficient (GHD) and non-GHD children who have received growth hormone (GH) in Australia.
Methodology : A retrospective study of a group of patients (1362 children) who commenced GH prior to 1 September 1990. Data were collected at 12 growth centres located in major cities throughout Australia. The data were transferred after informed consent to the national OZGROW database located at the Royal Alexandra Hospital for Children, Sydney, NSW. Of the 1362 children, 898 had received 3 years or more GH therapy and were eligible for this analysis. This cohort was then categorized by diagnosis. Growth response was assessed using height standard deviation score, estimated mature height, growth velocity (GV), GH dose and bone age (years).
Results : For children who completed 3 years therapy, the baseline characteristics among diagnostic groups were similar with mean height standard deviation score (SDS) less than – 3 SDS (except for the malignancy group) and mean GV ranging from 3.5 to 4.4 cm/year. The GV during the first year improved in all groups (7.7-9.4 cm/year) followed by an attenuated response during the second and third years of therapy. After 3 years GH therapy the GHD group with peak levels <10 mU/L demonstrated the greatest change in estimated mature height and height SDS. The GHD group with peak levels between £10 but <20 mU/L had a growth response similar to the non-GHD children for all outcome parameters. Change in bone age ranged from 3.1 to 3.8 years with no differences being noted between the diagnostic groups, nor consistently with pubertal status.
Conclusions : Australian GH guidelines have targeted very short children when compared to other series. This large cohort of non-GHD children has demonstrated short-term benefits of GH therapy; however, the long-term benefit remains unclear until these children reach final adult height.     

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 Response in Prepubertal Children with Idiopathic Growth Hormone Deficiency during the First Year of Treatment with Human Growth Hormone. Analysis of the Kabi International Growth Study.

ABSTRACT. In order that children with growth hormone deficiency (GHD) reach the goal of normal adult stature, treatment modalities need to be optimized. From the large database of patients enrolled in the Kabi International Growth Study (KIGS), 257 prepubertal patients with idiopathic GHD undergoing their first year of growth hormone (GH) substitution therapy were selected. A multiple regression analysis was performed to determine both auxiological factors characterizing the patients and the factors related to the chosen treatment modalities which are of significance for the observed magnitude of the growth response. Due to the structure of the data, pretreatment height velocity and bone age-derived auxiological data were not considered. It was observed that the magnitude of the growth response was inversely correlated with chronological age and relative height (HT SDS) at the start of GH treatment but was positively correlated with mid-parental height. The growth response was also positively correlated with the GH dose (IU/kg/week) and the frequency of GH injections per week. A regression equation using these five parameters was derived, allowing the growth response of these patients to be predicted. The extension of this analytical approach in the future will allow the treatment of patients with GHD to be tailored to individual requirements.