Treatment of short stature in renal disease with recombinant human growth hormone.

Six prepubertal children with chronic renal failure (group 1), six prepubertal children with renal transplants (group 2), and six pubertal children with renal transplants (group 3) who were short (mean height SD score, -3.2, range -4.5 to -1.6) and growing poorly (mean (range) growth velocity (cm/year) over the year before treatment: group 1, 4.8 (3.5-5.8), group 2, 2.3 (0.9-4.7), and group 3, 3.2 (0.5-6.5] were treated with recombinant human growth hormone 30 units/m2/week in daily doses for a median of 0.98 years (range 0.25-0.99). Mean (range) growth velocity over the treatment period increased significantly in all groups (group 1, 10.7 (8.8-12.3), group 2, 6.1 (2.7-10.8), and group 3, 6.0 (4.6-6.8]. There was, however, no improvement in height SD score for bone age in any group. The renal function of two children deteriorated after starting treatment with growth hormone, but it was not possible to say whether the growth hormone was responsible for this. The long term effects of treatment and its influence on final height are not yet known.     

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     

基因重组生长激素治疗青春期前特发性矮小疗效观察

目的探讨基因重组人生长激素（rhGH）对青春期前特发性矮小（ISS）的疗效。方法观察27例青春期前特发性矮小患儿,平均年龄（8.9±2.0）岁,身高（118.0±10.6）cm。治疗组13例,男10例,女3例,均接受基因重组人生长激素治疗,剂量（0.12±0.01）IU/kg,睡前皮下注射,疗程6个月至1年;对照组14例,男6例,女8例。结果治疗组患儿生长速率（GV）由治疗前（4.28±0.86）cm/a提高到（9.38±1.77）cm/a,P〈0.01;年龄身高标准差积分（HtSDSCA）由-2.28±0.48增至-1.72±0.62（P〈0.01）;骨龄身高标准差积分（HtS-DSBA）由-0.24±1.02增至0.27±0.99（P〈0.05）;与对照组比较,GV、HtSDS（CA）和HtSDS（BA）差异均有统计学意义（P均〈0.05）;两组△BA/△CA比较差异无统计学意义（P均〉0.05）。结论GH治疗能改善ISS儿童的GV及HtSDS（CA）、HtSDS（BA）,而骨龄（BA）加速不明显,疗效肯定。     

重组人生长激素治疗青春后期特发性矮小的疗效观察

No abstract available

     

Evaluation of growth hormone release and human growth hormone treatment in children with cranial irradiation-associated short stature

We studied nine children who had received cranial irradiation for various malignancies and subsequently experienced decreased growth velocity. Their response to standard growth hormone stimulation and release tests were compared with that in seven children with classic GH deficiency and in 24 short normal control subjects. With arginine and L-dopa stimulation, six of nine patients who received radiation had a normal GH response (greater than 7 ng/ml), whereas by design none of the GH deficient and all of the normal children had a positive response. Only two of nine patients had a normal response to insulin hypoglycemia, with no significant differences in the mean maximal response of the radiation and the GH-deficient groups. Pulsatile secretion was not significantly different in the radiation and GH-deficient groups, but was different in the radiation and normal groups. All subjects in the GH-deficient and radiation groups were given human growth hormone for 1 year. Growth velocity increased in all, with no significant difference in the response of the two groups when comparing the z scores for growth velocity of each subject's bone age. We recommend a 6-month trial of hGH in children who have had cranial radiation and are in prolonged remission with a decreased growth velocity, as there is no completely reliable combination of GH stimulation or release tests to determine their response.     

The effects of galanin on growth hormone secretion in children of normal and short stature

We have evaluated the effect of galanin (Gal), a newly identified hypothalamic peptide, on growth hormone (GH) secretion in 10 children with normal stature (NS), nine with constitutional growth delay (CGD), and five with isolated GH deficiency (IGHD). Gal was infused intravenously at a rate of 8 or 15 micrograms/kg/h. All children also underwent an acute oral clonidine test (0.15 mg/m2). In CGD children the mean plasma GH peak after 8 micrograms/kg/h of Gal infusion (13.3 +/- 1.7 ng/mL; mean +/- SEM) was higher (p less than 0.02) than in NS children (8.5 +/- 0.8 ng/mL). When the dose of Gal was increased to 15 micrograms/kg/h the mean plasma GH peak in CGD children (18.5 +/- 3.5 ng/mL) was still higher than in the NS group (13.2 +/- 2.9 ng/mL), although not significantly so. In IGHD children the mean plasma GH peak elicited by 8 or 15 micrograms/kg/h of Gal (3.8 +/- 0.7 and 3.9 +/- 0.5 ng/mL, respectively) was lower than that obtained in either CGD (p less than 0.0002) or NS children (p less than 0.001). In NS children the mean plasma GH peak after acute clonidine administration (22.3 +/- 3.0 ng/mL) was higher than that observed after either dose of Gal used (p less than 0.001 and p less than 0.05 with 8 and 15 micrograms/kg/h, respectively). In CGD or IGHD children mean plasma GH peak after acute clonidine (14.8 +/- 2.6 and 4.1 +/- 1.2 ng/mL, respectively) was not significantly different from that observed after either dose of Gal.(ABSTRACT TRUNCATED AT 250 WORDS)     

人生长激素同型异构体比例变化与特发性矮小症的相关性

人生长激素(human growth hormone,hGH)是出生后促进生长的主要激素,生长激素在调节生长的许多方面都起作用,生长激素缺乏会引起生长激素缺乏性矮小(growth hormone deficiency,GHD),但特发性矮小症患儿(idiopathic short stature,ISS)并不存在生长激素(GH)缺乏[1],其发病机制一直是研究的热点,有研究认为hGH同型异构体(humangrowth hormone isoforms,hGHI)比例的变化可能是ISS的发病机制之一[2,3],hGH有多种同型异构体,在垂体、胎盘和外周血中均存在,各种hGHI单体型的22kDa!hGHI含量最丰富,20kDa!hGHI含量次之,它们在结构上有…     

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.     

Growth-stimulating effects of recombinant human growth hormone in children with end-stage renal disease

Because patients with uremia have evidence for growth hormone resistance, we investigated whether this resistance can be overcome by administration of recombinant human growth hormone in supraphysiologic doses in children with severe uremia. Nine stunted children with end-stage renal disease (median age 5.8 years, median bone age 2.7 years) were treated with recombinant human growth hormone, 4 IU/m2/day subcutaneously, for a period of 1 year. Median height velocity was increased from 4.4 cm/yr before therapy to 8.0 cm/yr during treatment. Negative values for height velocity standard deviation scores for chronologic age were improved from a median of -2.6 to +1.5 without advancing bone age more than chronologic age. The growth hormone-insulin-like growth factor I resistance may be explained in part by the increased serum concentration of the high molecular weight insulin-like growth factor binding protein despite normal insulin-like growth factor I serum concentration. Treatment with recombinant human growth hormone improved the ratio between the serum concentrations of insulin-like growth factor I and its binding protein, and normalized the somatomedin bioactivity in the growth cartilage bioassay.     

Linear growth response to exogenous growth hormone in children with short stature

Response to growth hormone (GH) therapy was evaluated in 38 short children (28 males and 10 females; less than 1% in height for chronologic age [CA]) who were clinically categorized into three groups based on their endogenous mean 24-hour GH concentration (mean 24-hour GH) and peak GH response to two or more provocative agents (peak GH). All patients were treated with biosynthetic somatropin (human growth hormone) (0.15 to 0.30 mg/kg per week) injected subcutaneously three to seven times per week for a mean duration of 12.5 months. Group 1 consisted of 17 subjects (CA, 12.5 +/- 2.9 years [mean +/- SD]; bone age, 9.4 +/- 2.9 years; height velocity [HV], 3.4 +/- 1.8 cm/y; peak GH, 5.8 +/- 2.6 micrograms/L; mean 24-hour GH, 1.7 +/- 0.6 micrograms/L; and insulinlike growth factor-I, 0.40 +/- 0.24 U/mL. Group 2 consisted of 10 subjects (CA, 11.7 +/- 2.7 years; bone age, 9.2 +/- 3.0 years; HV, 3.4 +/- 1.6 cm/y; peak GH, 16.4 +/- 5.2 micrograms/L; mean 24-hour GH, 1.7 +/- 0.5 micrograms/L; and insulinlike growth factor-I, 0.49 +/- 0.27 U/mL. Group 3 consisted of 11 subjects (CA, 12.7 +/- 2.2 years; bone age, 10.2 +/- 2.4 years; HV, 3.5 +/- 1.5 cm/y; peak GH, 22.5 +/- 8.6 micrograms/L; mean 24-hour GH, 3.8 +/- 1.1 micrograms/L; and insulinlike growth factor-I, 1.07 +/- 0.69 U/mL. Following administration of somatropin, an increase (delta) in HV of 2.0 cm/y or greater occurred in 94% (16/17) of the group I subjects (delta HV of 5.1 +/- 2.6 cm/y), in 90% (9/10) of the group 2 subjects (delta HV of 4.3 +/- 2.2 cm/y), and in 73% (8/11) of group 3 subjects (delta HV of 3.7 +/- 2.3 cm/y). However, regardless of provoked and/or endogenous GH secretory dynamics, 88% of the children whose pretreatment HV was 2.0 cm/y or less, 94% whose pretreatment HV was between 2.0 and 4.0 cm/y, and 79% whose pretreatment HV was greater than 4.0 cm/y increased their HVs to 2.0 cm/y or greater while they were receiving somatropin. Significant negative correlations were observed between delta HV and pretreatment HV (r = -.67), delta HV and GH concentration expressed as a 24-hour area under the curve (r = -.33), and delta HV and peak GH (r = -.34).(ABSTRACT TRUNCATED AT 400 WORDS)     

Long-term treatment with growth hormone of children with short stature and normal growth hormone secretion.

Children with short stature but normal growth rate and/or normal growth hormone response to sleep and secretagogues were treated with recombinant methionyl human growth hormone, 0.3 mg/kg per week. In each year of treatment, about 80% of the subjects maintained an increase in growth rate greater than the defined limit (greater than 1 cm/yr above pretreatment growth rate) for continuation of human growth hormone treatment. Comparison of the group that continued to respond to human growth hormone with the group that did not maintain an accelerated growth rate did not reveal differences in bone age delay, sleep or secretagogue-stimulated human growth hormone secretion, degree of short stature either absolute or relative to target height, and somatomedin C concentration before or after initiation of therapy. The group that failed to respond to the human growth hormone treatment in the first year of treatment was younger and had a higher pretreatment growth rate. Review of the longitudinal growth curves revealed five patterns of response to human growth hormone treatment: (1) failure to increase growth rate in two subjects with height SD scores within 1 SD of target height, (2) failure to increase growth rate in five subjects with height SD scores greater than 1 SD less than the target height, (3) acceleration in growth rate in three subjects that was not maintained until achievement of a height within 1 SD of the target height, (4) acceleration of growth rate in five subjects that was maintained until achievement of a height within 1 SD of the target height, and (5) acceleration in growth rate that was maintained during the 3 years of treatment in 15 subjects who had not attained a height within 1 SD of the target height. We conclude that human growth hormone treatment of some but not all short children with "normal" growth hormone secretion will result in sustained acceleration of growth rate and attainment of prepubertal heights that are closer to but do not exceed their genetic height potential. A clinical trial of human growth hormone may be necessary to determine which subjects will benefit from the treatment.     

Adult height in children with idiopathic short stature treated with growth hormone

Idiopathic short stature (ISS) includes a heterogeneous group of patients with common characteristics to those of familial short stature and constitutional delay. Some authors state that these children can often respond to GH treatment, thus increasing their adult height. The aims of this study were to determine the effect of GH treatment (0.5-0.7 IU/kg/week) and the influence of some initial variables on adult height in patients with ISS. It was a non-randomized, observational study of 30 boys with ISS and a historical control group of 42 patients. The patients were followed until achieving their adult height. The mean height gain of the treated group attributable to GH was 4.5 cm. A stepwise regression model considering predicted adult height and target height as independent variables and final height as dependent variable gave an R2 coefficient of 0.38. We conclude that GH significantly increases final height in boys with ISS.     

Three-year data from a comparative study with recombinant human growth hormone in the treatment of short stature in young children with intrauterine growth retardation

Growth acceleration and bone maturation were studied for 3 y in 69 children with severe short stature and a history of intrauterine growth retardation (IUGR), to determine the effect of treatment with recombinant human growth hormone (r-hGH). The patients were enrolled in an open, multicentre trial and were randomly allocated to either the treated group (Group 1) or the control group (Group 2). The children in Group 1 were treated daily with 0.2 IU/kg/body weight (0.067 mg/kg) s.c, during 3 y and the children in Group 2 started the study with a 1-y observation period followed by a 3-y treatment period. At birth, their mean weight standard deviation score (SDS) was -2.5 and their mean length SDS -3.5. At baseline, the patients were prepubertal, non-GHdeficient, with no known dysmorphic features. Mean age was 4.5 y, bone age was 3.3 y, height SDS was -3.4, height velocity (HV) SDS was -1.6, and body mass index SDS was -1.4. After 1 y of treatment, linear HV in Group 1 increased in comparison with the pre-treatment period (from 5.7 ± 2.0 to 10.1 ± 1.7cm/y; p < 0:001)and with the firstyear of observation in Group2( p < 0:001). Increased HV was sustained during the second and third year of treatment and was significantly higher than at baseline. A similar growth pattern was seen during the 3y of GH treatment in Group 2. Mean height SDS for chronological age increased by 2.0 ± 0.7 in the two groups after 3 y of treatment. HV after 1 y of treatment was negatively correlated with growth velocity at baseline. Bone age remained retarded but increased with a mean of almost 4 y after 3y of treatment in both groups. Even at a dose that is three times the replacement dose treatment with r-hGH was well tolerated. From these results, we conclude that r-hGH treatment over 3 y can induce sustained catch-up growth in young children with severe short stature and a history of IUGR. Long-term studies are needed to assess ultimate effects on final height.     

Short-term treatment of short stature and subnormal growth rate with human growth hormone

Forty-eight children with short stature, growth rate less than 4 cm/yr, and normal growth hormone response to secretagogues were given exogenous human growth hormone (hGH) for 6 months to determine its effect on the short-term growth rate in these children. All except three had an increase in growth rate with hGH therapy. The mean +/- SD pretreatment growth rate (3.4 +/- 0.8 cm/yr) was significantly less than either the growth rate during 6 months of hGH therapy (6.9 +/- 2.6 cm/yr) or after therapy (4.1 +/- 1.8 cm/yr). Several patterns of response were observed after treatment was stopped: the mean growth rate in 22 children decreased after treatment but remained above basal rates, the mean growth rate in seven children was similar to the rates during treatment, and the mean growth rate in 16 children was less than basal rates. Twenty children received therapy for an additional 6 months and had a mean increase in growth rate from 3.6 +/- 1.3 to 6.7 +/- 2.4 cm/yr. The decreased growth rate after discontinuation of treatment and increased rate with resumption of therapy indicates that maintenance of the increased growth rate might be dependent on continuation of hGH therapy.     

重组人生长激素治疗特发性矮小12个月疗效评估

目的 分析重组人生长激素(rhGH)对特发性矮小（ISS）患儿的治疗效果和影响因素,为寻求优化治疗效果的途径提供参考依据。 方法 回顾性分析2003年2月至2011年7月在首都儿科研究所生长发育门诊确诊为ISS患儿的临床资料,依据是否予rhGH治疗分为rhGH组和对照组。以身高标准差变化（ΔHtSDS）和生长速度（GV）作为评估指标进行疗效和影响因素分析。分析治疗期间骨龄、身高年龄及胰岛素样生长因子(IGF-1)水平的变化。 结果 rhGH组35例,对照组33例进入分析。①rhGH组治疗前、治疗后12个月HtSDS呈增长趋势(P<0.05);对照组均未见升高趋势。治疗后0～3个月的ΔHtSDS水平为(0.22±0.13),治疗后~6、~9和~12个月分别为(0.20±0.10)、(0.12±0.14)和(0.14±0.15),呈降低趋势,但差异无统计学意义。治疗后0～3个月GV为(10.78±2.70) cm·year-1,治疗后~6、~9和~12个月分别为(10.52±2.44)、(8.31±2.78)和(8.50±2.29) cm·year-1,呈降低趋势,但差异无统计学意义。治疗后0~6个月ΔHtSDS和GV水平均显著高于～12个月［ΔHtSDS :(0.43±0.20) vs (0.27±0.24), GV: (10.48±2.17) vs (8.48±2.39) cm·year-1］。②治疗后12个月的ΔHtSDS水平与治疗开始时的年龄呈负相关,与治疗后0～3个月的ΔHtSDS呈正相关;治疗后12个月的GV水平与治疗前的GH峰值和治疗后3个月的GV水平呈负相关。③治疗后1年青春期前、青春早中期和青春后期ΔHtSDS差异总体上有统计学意义（P=0.016）,其中青春期前显著高于青春早中期和青春后期;GV差异无统计学意义。④rhGH组治疗后12个月的骨龄变化差异无统计学意义,身高年龄显著高于对照组。⑤rhGH组IGF-1水平在治疗后1个月升高较明显,之后升高趋势减缓。 结论 rhGH用于ISS患儿的治疗应尽量选择青春期前;治疗后3个月的效果可作为第1年治疗效果的预测因素;rhGH治疗不会使ISS患儿骨龄明显提前。     

重组人生长激素改善ACAN基因变异致家族性矮小的疗效观察及文献复习

目的观察重组人生长激素(rhGH)改善ACAN基因变异致家族性矮小患者身高的疗效。方法回顾分析2个ACAN基因变异致家族性矮小家系rhGH治疗的临床资料,并检索相关文献进行分析。结果先证者1,男,4岁1个月,身高90.5 cm(-3.6 SD),体质量13.5 kg,无明显骨骼畸形;骨龄示5岁6个月龄;基因检测示ACAN基因c.5026_5027del(p.Ser 1676 Ter)杂合缺失变异;予rhGH,50μg/(kg·d)治疗,第1年身高增加13 cm(103.5 cm,-1.8 SD),至第18个月身高增加17.1 cm(107.6 cm,-1.7 SD)。先证者2,男,3岁,身高82 cm(-3.9 SD),体质量12 kg,无明显骨骼畸形;骨龄示1岁6个月龄;基因检测示ACAN基因c.1504C>T(p.R 502C)杂合错义变异;予rhGH,33μg/(kg·d)治疗,第1年身高增加12 cm(94.0 cm,-2.6 SD),至第22个月身高增加17 cm(99.0 cm,-2.68 SD)。结论ACAN基因c.5026_5027 del杂合缺失变异以及c.1504C>T错义变异可引起家族性矮小;rhGH治疗短期可有效改善ACAN基因致家族性矮小患儿的身高。     

重组人生长激素对不同生长激素分泌状态青春前期矮小患儿近期疗效分析

目的探讨部分性生长激素缺乏症（pGHD）患儿在重组人生长激素（rhGH）治疗后早期追赶性生长的规律。方法回顾性分析62例青春前期不同生长激素（GH）分泌状态矮小患儿用rhGH治疗后,近期（1．5年）追赶性生长指标（生长速度和身高Z分增值）和促生长素轴实验室指标的变化。其中,完全性生长激素缺乏症（cGHD）27例;非GH缺乏性矮小（NGHD）12例;pGHD23例,按GH激发峰值7ng／ml分为pGHD-1（12例）和pGHD-2（11例）两个亚组。结果cGHD和NGHD初始追赶性生长的幅度相似,但NGHD组持续时间较短。pGHD和cGHD以同一rhGH生理替代量治疗后,促生长的应答（生长速度和AIGFBP-3SDS）pGHD-1和cGHD差异无统计学意义,但pGHD-2却低于cGHD,而与NGHD差异无统计学意义。结论GH激发试验的诊断界值选用7ng／ml有更合理的依据,诊断pGHD时尤应审慎。pGHD-2组治疗早期的生长追赶不完全可能与rhGH剂量相对不足有关。     

Correlation between pituitary growth hormone reserve and degree of growth failure in children with short stature

The correlation between a releasable pituitary growth hormone (GH) pool and degree of growth failure was examined in 30 children with GH deficiency (group I) and 19 children with normal short stature (group II). Based on the responsiveness of GH to GH-releasing hormone (GHRH), group I, with low GH responses (below 7 ng/ml) to both insulin and arginine, was classified into three subgroups; I_a (peak value less than 10 ng/ml, n=19), I_b (10–20 ng/ml, n=5) and I_c (above 20 ng/ml, n=6). Group II, with a GH response above 10 ng/ml to either insulin or arginine, was also divided into II_a (below 20 ng/ml, n=5) and II_b (above 20 ng/ml, n=14). Body length and growth velocity in I_a and I_b were significantly reduced vs I_c; bone age in I_a was retarded vs I_c; plasma somatomedin C (Sm-C) levels in I_a and I_b were decreased vs I_c, who had almost normal levels (0.90±0.55 U/ml). The incidence of other combined pituitary hormone deficiencies and previous perinatal distress was definitely high in I_a and I_b, but zero in I_c. In group II also, body length and growth velocity were significantly decreased in II_a vs II_b (P<0.01). These results indicate that [1] the pituitary reserve of GH estimated by GHRH is a good reflection of the degree of growth failure in GH-deficient children as well as in those of normal short stature, [2] hypothalamic GHRH deficiency tends to have a milder effect on growth retardation than pituitary GH deficiency, and [3] normal short children with a diminished GH reserve may be potential candidates for the GH treatment.Abbreviations ACTH adrenocorticotropin - LH luteinizing hormone - LH-RH luteinizing hormone-releasing hormone - GH growth hormone - GHRH growth hormone-releasing hormone - Sm-C somatomedin C - TRH thyrotropin-releasing hormone - TSH thyrotropin