Growth hormone for children with chronic renal failure and on dialysis

We studied all children with CRF who received recombinant human growth hormone (rhGH) for more than a year (mean±SD duration of therapy 3.7±2.5 years) over an 11-year period. There were 32 children. Twenty-one children were conservatively managed, with a mean glomerular filtration rate (GFR) of 24±12 mL min^–1/1.73 m² at the start of rhGH. Their height standard deviation score improved from –2.5±1.4 to –2.1±0.7 at 1 year (P=0.3), –2.0±0.7 at 2 years (P=0.01), and –1.6±0.6 at 3 years (P=0.001). After that there was no improvement. Eleven children were on dialysis, six on haemodialysis (HD) and five on peritoneal (PD). Ht SDS improved from –2.7±0.5 to –2.3±0.5 at 1 year (P=0.02). Thereafter there was no further improvement. RhGH was stopped because of transplantation in 29 patients at a mean±SD age of 12.1±4.0 years. Mean Ht SDS was –1.8±0.8 at transplant and there was no change over the following 5 years. In conclusion, treatment with rhGH resulted in improvement in Ht SDS in conservatively managed CRF for up to 3.0 years and for 1 year in children on dialysis. Discontinuation of rhGH after transplantation resulted in little change in Ht SDS.     

Recombinant human growth hormone treatment of children on hemodialysis

Forty-two children, aged 2–21.5 years on hemodialysis with a height below –2.0 standard deviation score (SDS) for age, were selected to receive recombinant human growth hormone (rhGH) therapy at 17 French centers. Of the 42 children, 36 were prepubertal and 8 were in early puberty (testicular volume between 4 and 8 ml for boys, breast development B2 or B3 in girls). All received 1 IU/kg per week by daily subcutaneous injection for 1–5 years. The year before rhGH therapy served as a control period. During the 1st year of treatment, mean growth velocity increased from 3.5 to 7.0 cm/year (P <0.0001) and was always over 2.5 cm/year. This velocity allowed a catch-up growth of +0.5 height SDS. Neither weight nor the body mass index varied compared with the pretreatment year. No change was observed in urea, creatinine, or glucose tolerance. The mean increment in bone age was 0.9 years. The mean growth velocity decreased over subsequent years (P <0.0001), but remained higher than the prestudy velocity. A significant negative correlation was observed during the 1st year between the increase in growth velocity and the prestudy velocity (P <0.0001), with the least gain in patients who had the best spontaneous velocity. Pubertal status had no influence on response to rhGH. No significant side effects were observed during the 103 treatment-years. Five patients developed secondary hyperparathyroidism and 1 suffered from acute pancreatitis, but the relationship with rhGH therapy remains uncertain. rhGH therapy appears indicated for children on hemodialysis, even though the potential benefits appear somewhat lower for those with a spontaneous growth velocity over 6 cm/year. Received April 18, 1997; received in revised form October 23, 1997; accepted October 28, 1997     

Factors influencing the response to growth hormone in children with renal disease

The effects of age, height velocity over the preceding year, glomerular filtration rate (GFR) and prednisolone dose on growth response have been assessed by single and multiple linear regression analysis in 23 prepubertal children [age, mean (SD), 8.2 (2.5) years] with chronic renal failure (CRF) and 16 prepubertal children [12.1 (2.3) years] with renal transplants treated for 1 year with recombinant human growth hormone (rhGH), 30 U/m² per week. Height velocity [mean (SD), cm/year increased from 4.7 (1.3) to 9.7 (2.1) (P<0.0001) in the CRF group and 3.1 (1.6) to 7.3 (2.8) (P<0.0001) in the transplant group. In the CRF group, there was a correlation between age and height velocity, both in the pretreatment year (r=–0.755,P<0.0001) and during treatment (r=–0.421,P=0.045). There was no correlation between pretreatment height velocity or GFR and response to rhGH. In the transplanted children height velocity during the treatment year correlated with age (r=–0.647,P=0.007), prednisolone dose (r=–0.689,P=0.003), GFR (r=0.542,P=0.030) and pretreatment height velocity (r=0.655,P=0.006). Multiple regression analysis showed prednisolone dose and age to be the most important predictors of response.     

Long-term results of rhGH treatment in children with renal failure: experience of the French Society of Pediatric Nephrology

Few publications have described the long-term effects of recombinant human growth hormone (rhGH) in uremic patients. This study reports the results of rhGH therapy at the end of treatment and at adult age in 178 French patients. At enrollment, 63 patients were under conservative treatment (CT), 40 under hemodialysis (HD), and 75 had a functioning renal transplant (RT). Under rhGH treatment, height velocities (HV) significantly increased in all patients, but the effect was significantly better in the CT group. The HV gain (HV under rhGH-HV before treatment) was similar in all three groups. Increases in HV allowed height standard deviation scores (SDS) catch up, and this effect persisted over a 5-year period. SDS height at the completion of treatment was significantly related to group (best in CT) and response to treatment during the first year. Data on adult height was available for 102 patients. Mean adult height was 162.2 cm in men and 152.9 cm in women, and 46% were > −2 SDS for height. Adult height SDS was correlated with height SDS and spontaneous HV before treatment and effect of treatment. Analysis of adult height in the 49 patients who entered the protocol with a height SDS between −2 and −3 (the current recommendation for rhGH use) revealed that 65% had an adult-height SDS >−2. These adult heights were significantly better if compared with historical cohorts of patients not treated by rhGH; rhGH significantly improves the adult-height prognosis of uremic patients suffering from growth retardation. Early rhGH administration during CT gives better height SDS at both the end of rhGH therapy and in adulthood. Members of the French Society of Pediatric Nephrology: J.L. André, A. Bensman, E. Bérard, J.P. Bertheleme, F. Bouissou, B. Boudailliez, F. Brou, M. Broyer, A. Burguet, G. Champion, P. Cochat, M. Dehennault, G. Deschênes, P. Desprez, R. Dumas, M. Fischbach, M. Foulard, M.T. Freycon, M.F. Gagnadoux, S. Gié, G. Guest, C. Guyot, G. Landthaler, M.P. Lavocat, C. Loirat, M.A. Macher, D. Morin, C. Mousson, P. Niaudet, H. Nivet, J.B. Palcoux, G. Picon, B. Roussel, M. Tsimaratos     

First-year response to rhGH therapy in children with CKD: a National Cooperative Growth Study Report

A clear definition of the appropriate growth response during recombinant human growth hormone (rhGH) treatment has never been established in the pediatric chronic kidney disease (CKD) population. We present here data from Genentech’s National Cooperative Growth Study (NCGS) on the first-year growth response in prepubertal children with CKD. Using NCGS data, we constructed response curves for the first year of rhGH therapy in 270 (186 males, 84 females) naïve-to-treatment, prepubertal children with CKD prior to transplant or dialysis. Data from both genders were combined because gender was not significantly related to height velocity (p?=?0.51). Response to rhGH was expressed as height velocity (HV) in cm/year. Mean, mean ± 1SD, and mean ? 2SD for HV during the first year of rhGH treatment as well as pretreatment HV were plotted versus age. Age-specific HV plots for rhGH-treated children with CKD are presented. At all ages, the first-year mean HV was greater than the mean pretreatment HV. The mean ? 2SD for HV in children on rhGH treatment was similar to the mean pretreatment HV. These growth plots will be useful to clinicians for assessing a patient’s first-year growth response. We propose that a HV below the mean ? 1SD is an inadequate response. These curves may help identify patients with a suboptimal growth response due to confounding medical factors and/or non-compliance.     

Recombinant human growth hormone in infants and young children with chronic renal insufficiency

Children with chronic renal insufficiency (CRI) secondary to congenital structural abnormalities frequently have significant growth retardation by 2 years of age. In a multicenter placebo-controlled study of the use of recombinant human growth hormone (rhGH), 30 of 125 (24%) participants were<2.5 years of age at enrollment. Since the treatment arms of the study were balanced for age at randomization, data for these patients were examined for efficacy and safety. During the first 2 years of the study, approximately two-thirds of the patients (n=19) received rhGH 0.05 mg/kg per day subcutaneously and one-third (n=11) received placebo injections. At entry into the study, the mean (± SD) calculated creatinine clearance was 29.2±14.3 (range 12.0–63.7) ml/min per 1.73 m² in the rhGH-treated group and 23.3±15.1 (range 8.0–59.4) ml/min per 1.73 m² in the placebo-treated group. The 1st year growth rate was 14.1±2.6 cm/year for the rhGH-treated group and 9.3±1.5 cm/year in the placebo-treated group (P<0.00005). During the 2nd year of the study, the growth rate was 8.6±1.2 cm/year in the rhGH-treated group compared with 6.9±1.0 in the placebo groupP=0.025). The height standard deviation score was +2.0±0.7 for the rhGH-treated group compared with –0.2±1.1 in the placebo-treated group (P<0.00005) during the 2 years of the study. Minor adverse events occurred with similar frequency in both groups. These data suggest that rhGH is efficacious and safe in children with CRI under age 2.5 years. rhGH therapy may correct significant loss of growth at this age when used in conjunction with optimal medical management.     

Recombinant human growth hormone treatment of children with chronic renal failure: long-term (1- to 3-year) outcome

Treatment of nine boys, aged 2.8–16.3 years, with growth retardation consequent to chronic renal failure (CRF), with recombinant human growth hormone (rhGH) for 12–36 months demonstrated a significant improvement in growth velocity at each 12-month interval compared with that achieved the year prior to treatment. Despite the acceleration in growth velocity the bone age did not increase more than the increase in chronological age during the period of treatment. The mean calculated creatinine clearance did not decrease significantly during the 36 months of treatment; however, two patients required institution of dialysis at 18 and 30 months following the initiation of rhGH treatment. There was no exacerbation of the glucose intolerance of uremia following rhGH treatment. Currently, six of seven patients who have been treated for more than 24 months have achieved sufficient acceleration of growth velocity to attain a standard deviation score that was more positive than –2.00, and are above the 5th per centile for chronological age on the growth curve. These data indicate that rhGH treatment of growthretarded children with CRF results in accelerated growth velocity during the 2nd and 3rd years of treatment, and demonstrate the potential for such children to achieve normal stature for chronological age despite the continued presence of renal failure.     

Recombinant human growth hormone treatment of children following renal transplantation

Nine growth-retarded renal allograft recipients received either thrice weekly or daily subcutaneous recombinant human growth hormone (rhGH) for 6–30 months. The annualized growth velocity for the initial year of rhGH treatment was significantly greater than that of the preceding year (2.5±2.1 vs 5.7±2.7;P<0.0001). There was no advancement in bone age greater than the increase in chronological age, no significant increase in the mean fasting serum glucose or insulin levels, nor significant decrease in the calculated creatinine clearance following rhGH treatment. However, two patients experienced rejection episodes following rhGH treatment indicating the potiental adverse consequences of the treatment on allograft function. This will require further delineation in prospective controlled studies. The serum insulin-like growth factor-1 levels significantly increased at 6 months (P<0.009) and 12 months (P<0.002) following rhGH treatment compared with baseline values. These preliminary data indicate that rhGH treatment may be effective in improving the growth velocity of growth-retarded renal allograft recipients.     

Growth charts for prepubertal children with chronic renal failure due to congenital renal disorders

Despite the high prevalence of and therapeutic attention to growth failure in children with chronic renal failure (CRF), systematic evaluation of spontaneous growth in CRF are lacking. Therefore, we collected retrospectively longitudinal growth and biochemical data in 321 prepubertal patients treated for CRF due to congenital renal disorders. Data were recorded at 3-month intervals during the first 2 years of life and 6-monthly thereafter, up to the age of 10 years. Around 100 measurements were available per age interval. Mixed-longitudinal percentile curves of height and height velocity were constructed. Moreover, a statistical comparison with the heights and height velocities of healthy children and an evaluation of the effect of biochemical parameters on growth was performed. The CRF children had normal heights at birth but dropped below the 3rd normal percentile during the first 15 months of life. Thereafter, growth patterns usually were percentile parallel, with a mean height standard deviation score (SDS) of –2.37±1.6. Height velocities were consistently lower in patients with glomerular filtration rates (GFRs) below onethird of the lower normal limit (25 ml/min per 1.73 m² for patients >1 year) than in patients with better renal function. This difference in growth rates resulted in a mean height SDS of –1.65±1.5 SDS and –2.79±1.4 SDS (age 1–10 years) in the subgroups with relatively better and worse GFR, respectively. Regression analysis confirmed that GRF was a weak but significant predictor of height velocity SDS in most age groups.Study group members: I. Rätsch (Ancona), K. Michelis, T. Kapogiannis (Athens), F. Jung, T. Lennert (Berlin I), S. Gellert (Berlin II), T. Tulassay, P. Sallay (Budapest), T. von Lilien, D. Michalk (Cologne), M.-A. von Wendt-Göknur (Erlangen), K. E. Bonzel (Essen), R. Gusmano, E. Verrina (Genova), G. Offner (Hannover), O. Mehls, A.-M. Wingen, C. Fabian-Bach (Heidelberg, coordinators), A. Appiani, A. Bettinelli (Milan), J. Feber (Prague), G. Rizzoni, S. Picca (Rome), H. J. Stolpe, M. Wigger (Rostock), J. Kist-van Holthe, E. Wolff (Rotterdam, coordinators for the centers Amsterdam, Antwerp, Groningen, Nijmegen, Rotterdam), U. Berg (Stockholm), M. Fischbach (Strasbourg), E. Dobos (Szeged), E. Balzar (Vienna), T. Neuhaus (Zurich).     

Effects of growth hormone on kidney function in pediatric transplant recipients

Recent evidence suggests that treatment with recombinant human growth hormone (rhGH) after a successful kidney transplant improves the growth rate of children with short stature. We prospectively investigated eight children (6 boys, 2 girls), focusing on acute rejection episodes and changes in serum creatinine levels during rhGH treatment. The children (mean age 11.6±3.4 years) received rhGH daily (0.04–0.05 mg/kg subcutaneously). Seven patients completed at least 12 months (20±8 months) of rhGH treatment. Their mean serum creatinine level was 1.3±0.7 mg/dl 12 months before, and increased to 3.4±4.2 mg/dl after 12 months of rhGH treatment, but did not achieve statistical significance (P=0.06). Their mean calculated glomerular filtration rate was 58±20 ml/min per 1.73 m² 12 months before, and decreased to 38±21 ml/min per 1.73 m² 12 months before, and decreased to 38±21 ml/min per 1.73 m² after 12 months of rhGH treatment, but did not achieve statistical significance (P=0.08). Of the seven patients, two developed acute rejection after 5 and 6 rejection-free years; three lost their grafts and returned to dialysis. These preliminary observations describe untoward renal events in children receiving rhGH treatment after a kidney transplant.     

Parathyroid hormone levels in pubertal uremic adolescents treated with growth hormone

We have previously described severe hyperparathyroidism during the pubertal growth spurt in three uremic adolescents treated with recombinant human growth hormone (rhGH). Here we investigate the possible role of puberty in the genesis of hyperparathyroidism during rhGH treatment of a large cohort of patients. Data from 67 uremic patients treated with rhGH from five Italian pediatric nephrology centers were retrospectively recorded every 3 months starting 1 year before rhGH administration. The mean (±SD) rhGH treatment observation period was 19.9±5.9 months. The mean age at the start of rhGH treatment was 8.3±3.6 years. Of the 67 patients, 15 reached pubertal stage 2 during the 1st year of rhGH treatment and 12 of these 15 progressed to pubertal stage 3. The relative increase in parathyroid hormone (PTH) levels after rhGH initiation was greater in pubertal [1.95, 95% confidence interval (CI) 1.43–2.66] than in prepubertal patients (1.19, 95% CI 1.01–1.40). Increases in PTH levels were significantly different between the two groups (=1.64, 95% CI 1.16–3.19, P=0.007). Multiple regression analysis showed an inverse correlation between PTH and calcium levels and a positive correlation between PTH and pubertal stage 3. There was no correlation with phosphate levels and calcitriol dosage. In conclusion, these results suggest that in uremic adolescents treated with rhGH puberty may influence PTH levels.     

Plasma growth hormone-binding activity is low in uraemic children

Plasma growth hormone-binding protein (GH-BP) activity was evaluated in two groups of prepubertal children with chronic renal failure (CRF) who had been treated with recombinant human GH (rhGH). Group 1 consisted of eight children (mean chronological age 10.8 years) with advanced renal failure; group 2 consisted of nine children (mean chronological age 6 years) presenting with end-stage renal disease, who were on dialysis. Before treatment the specific binding of (¹²⁵I)hGH to highaffinity GH-BP was low in the two groups (group 1, 17.3±1.6% of radioactivity; group 2, 14.2±1.4%) compared with the mean value obtained in normal prepubertal children (24.8±1.7%). No significant changes in GH-BP activity were found during the 1st year of GH therapy, although growth velocity and plasma levels of insulin-like growth factor-I increased significantly in both groups. The low GH-binding activity found in children with CRF supports the state of GH resistance. The reason for the absence of a GH-BP response to GH therapy has to be clarified.     

Accelerated growth in short children with chronic renal failure treated with both strict dietary therapy and recombinant growth hormone

In a 12-month study, nine boys, aged 4.8–15.6 years, with bone ages 4.6–13 years, with moderate to severe chronic renal failure and resultant growth failure were treated with daily recombinant human growth hormone (rhGH), in conjunction with a strict low-protein/low-phosphate diet supplemented with keto and amino forms of the essential amino acids, histidine and additional energy. Improved growth had previously been observed with this dietary management over that obtained with conventional treatment for chronic renal failure. Each child had been on this diet for at least 2 years before rhGH was commenced. Mean height velocity increased from 4.6±1.3 to 9.0±1.3 cm/year (P<0.001) in the pre-pubertal group, and in the pubertal group from 5.4±1.4 to 10.4±1.8 cm/year (P<0.01). The mean height velocity standard deviation scores (SDSs) increased from –1.2±0.6 to +2.3±0.9 (P<0.001) in the pre-pubertal group and from –0.4±0.6 to +1.9±1.1 (P<0.01) in the pubertal group. Mean height SDS for chronological age increased from –2.2±0.7 to –1.5±0.5 (P<0.01) in the pre-pubertal group and from –1.9±0.7 to –1.3±0.9 in the pubertal group (P<0.02). There was no significant deterioration in renal function or renal bone disease, and bone age did not advance more than chronological age over the 12-month period.     

Growth after renal transplantation: Correlation with immunosuppressive therapy

The growth data for children transplanted between 1973 and 1987 were analysed according to their immunosuppressive regimen. All patients treated before 1985 received conventional treatment (prednisone, azathioprine); 37% of the prepubertal children with a follow-up of longer than 2 years showed catch-up growth, and 30% of the pubertal children exhibited a normal adolescent growth spurt. Reduced renal function and corticosteroid treatment are the two main causes of growth delay. The children transplanted between January 1985 and September 1987 were given either triple therapy [cyclosporine (CsA), prednisone, azathioprine] or conventional treatment after randomisation. Growth data were significantly better with CsA. The mean height gain for prepubertal children was +0.24 SD/year on triple therapy and +0.14 SD/year on conventional therapy during the 1st year after transplantation; and 0.4 SD/year and 0 SD/year during the 2nd year (P<0.05). The mean height gain for pubertal children was 5.6 cm/year on triple therapy and 3.6 cm/year on conventional therapy (P<0.005). The patients on triple therapy also received a significantly lower cumulative dose of prednisone. Some selected patients on triple therapy were taken off prednisone 12 months after transplantation. All patients showed catch-up growth (+0.83 SD/year in prepubertal children, 7.2 cm/year in pubertal children). In conclusion, protocols including CsA and the lowest cumulative dose of steroid (with alternate-day or even steroid withdrawal) allow the best restoration of growth.     

Results of recombinant growth hormone treatment in children with end-stage renal disease on regular hemodialysis

Children with chronic kidney disease are at high risk for growth retardation and decreased adult height. Growth hormone (GH) treatment is known to stimulate growth in children with short stature suffering from chronic kidney disease. However, the extent to which this therapy affects final adult height is not known. This study was performed on 15 patients with end-stage renal disease (ESRD) on regular hemodialysis to detect the effect of using recombinant human growth hormone (rhGH) on growth of patients with ESRD on regular hemodialysis and comparing this effect with the growth velocity in the same group without using rhGH in the year before therapy. There were eight females and seven males with mean age 10.6 ± 2.8 (range 5-14 years). For each patient, recombinant GH was given for one year, three-times weekly. The data of these 15 patients was compared with the year before treatment versus data of the same group of patients after six months and after one year of rhGH therapy. Our results showed that, in the year before therapy, height of these patients increased from a mean of 112.1 ± 11.6 cm to 112.7 ± 11.5 cm, which is a non-significant increase statistically (P >0.05) as well as clinically (mean growth velocity 0.6 cm/year), while height of these patients increased from a mean of 112.7 ± 11.5 cm at the start of therapy to 116.8 ± 11 cm after therapy for one year, which, although statically not significant (P >0.05), was of clinical significance as it makes rate of increase, i.e. the mean growth velocity, 4.1 cm/year close to the normal growth velocity, which is 5 cm/year, before puberty. rhGH therapy for patients with ESRD on regular hemodialysis is helpful in height gain and catch-up growth even when given three-times per week instead of five- or six-times per week. We recommend giving rhGH therapy as a routine supplementation to pediatric patients before epiphyseal closure.     

Use of rhGH in children with chronic kidney disease: lessons from NAPRTCS

We evaluated the utilization and potential benefits of recombinant human growth hormone (rhGH) in children with chronic kidney disease (CKD) and following renal transplantation in a large patient cohort. We queried the chronic renal insufficiency (CRI), dialysis, and transplant registries of the North American Pediatric Renal Trials and Collaborative Studies (NAPRTCS) to characterize the frequency of rhGH utilization, factors related to its usage, and the relationship between rhGH usage and catch-up growth. Data from 6,505, 5,122, and 4,478 CRI, dialysis, and transplant patients, respectively, was evaluated. Percentage utilization of rhGH 2 years after registry entry was 22%, 33%, and 3% in children with a height standard deviation score (SDS) <−1 and age <17 years (termed candidate group) in CRI, dialysis, and transplant patients, respectively. Multivariate logistic regression analysis showed that the likelihood of using rhGH was significantly correlated with age, gender, geographical region of residence and height category within the candidate group (p < 0.01). The use of rhGH was associated with catch-up growth in 27%, 11%, and 25% of candidate CRI, dialysis, and transplant patients, respectively. In the candidate group, percentage catch-up growth was highest in children who were Tanner stage 1–2, who comprised 19.4%, 7.1%, and 25.5% of the CRI, dialysis, and transplant patients, respectively. Using multiple regression analysis, the estimated impact of rhGH on final adult height (age >19 years) was 0.80, 0.50, and 0.19 SDS, in CRI, dialysis, and transplant patients, respectively. Thus, rhGH can improve height gain in some children with CKD. The use of rhGH appears to be most effective in prepubertal children with CRI.     

Growth of children following the initiation of dialysis: a comparison of three dialysis modalities

Maintenance dialysis usually serves as an interim treatment for children with end-stage renal disease (ESRD) until transplantation can take place. Some children, however, may require dialytic support for an extended period of time. Although dialysis improves some of the problems associated with growth failure in ESRD (acidosis, uremia, calcium, and phosphorus imbalance), many children continue to grow poorly. Therefore, three different dialysis modalities, continuous ambulatory peritoneal dialysis (CAPD), cycler/intermittent peritoneal dialysis (CPD), and hemodialysis (HD), were evaluated with regard to their effects on the growth of children initiating dialysis and remaining on that modality for 6–12 months. Growth was best for children undergoing CAPD when compared with the other two modalities with regard to the following growth parameters: incremental height standard deviation score for chronological age [–0.55±2.06 vs. –1.69±1.22 for CPD (P<0.05) and –1.80±1.13 for HD (P<0.05)]; incremental height standard deviation score for bone age [–1.68±1.71 vs. –2.45±1.43 for CPD (P=NS) and –2.03±1.28 for HD (P=NS)]; change in height standard deviation score during the dialysis period [0.00±0.67 vs. –0.15±.29 for CPD (P=NS) and –0.23±.23 for HD (P=NS)]. The reasons why growth appears to be best in children receiving CAPD may be related to its metabolic benefits: lower levels of uremia, as reflected by the blood urea nitrogen [50±12 vs. 69±16 mg/dl for CPD (P<0.5) and 89±17 for HD (P<0.05)], improved metabolic acidosis, as indicated by a higher serum bicarbonate concentration [24±2 mEq/l vs. 22±2 for CPD (P<0.05) and 21±2 for HD (P<0.05)]. In addition, children undergoing CAPD receive significant supplemental calories from the glucose absorbed during dialysis. CAPD, and possibly, other types of prolonged-dwell daily peritoneal dialysis appear to be most beneficial for growth, which may be of particular importance for the smaller child undergoing dialysis while awaiting transplantation.     

Insulin-like growth factor-1, growth hormone-dependent insulin-like growth factor-binding protein and growth in children with chronic renal failure

Insulin-like growth factor-binding protein-3 (IGFBP-3) and insulin-like growth factor-1 (IGF-1) levels were measured by specific radioimmunoassays in children with all degrees of chronic renal failure (CRF). Study group 1 comprised 29 children (10 on dialysis) who had been studied one to four times over 2 years to determine whether IGF-1 and IGFBP-3 levels differed from those in age-matched healthy children and to examine the relationship between these levels and heights. IGF-1 and IGFBP-3 levels did not differ from those in normal children. IGF-1 and IGFBP-3 were significantly correlated, increased with pubertal stage in all children and with age in non-dialysis patients. IGF-1, but not IGFBP-3, correlated with age in dialysis patients. There was no correlation between IGF-1 or IGFBP-3 levels (corrected for age) and height standard deviation score (SDS) in either non-dialysis or dialysis patients. Study group 2 comprised 19 children (7 on dialysis) who were studied prospectively for 1–2 years to examine the relationship between IGF-1 and IGFBP-3 levels, growth rates and nutritional parameters. Mean values of IGF-1 and IGFBP-3 (corrected for age) did not change over 1-year periods, while height SDS fell by –0.38 ±0.21 SD/year in dialysis patients and by –0.11 ±0.29 SD/year in non-dialysis patients. No significant correlations were found between IGF-1 or IGFBP-3 levels and growth rates or nutritional parameters. Thus growth retardation in children with CRF is not related to circulating levels of IGF-1 or IGFBP-3.     

Growth hormone treatment of renal growth failure during infancy and early childhood

Despite major progress in dialysis, nutrition and drug treatment in the past 20 years, growth of infants and toddlers with chronic kidney disease (CKD) remains a major challenge in paediatric nephrology. Our hypothesis is that early growth deficit is one of the most important factors for impaired final height in children with CKD, and we conclude that early implementation of recombinant human growth hormone (rhGH) therapy should be offered to infants with growth failure. Infants with delayed growth, adequate caloric intake and stable parameters of bone metabolism are candidates for rhGH therapy. One predictive factor for the selection of infants for rhGH treatment may be growth retardation at birth. Our conclusion from the limited published data is that the use of rhGH in young children with CKD is effective and safe. Compared with its use in older children, the early use of growth hormone requires lower absolute dosages of rhGH, which therefore reduce the annual treatment costs and allow earlier renal transplantation. Furthermore, an early start on rhGH improves the psychosocial situation later in childhood and may lead to a further improvement in adult height. A multi-centre randomised controlled study should be initiated to analyse the short-term and long-term effects of early rhGH therapy on infants with CKD. Remark from the EditorsThe article by Mencarelli et al. was published in the May 2009 issue of the Journal and can be found at doi:.     

Recombinant human growth hormone treatment after liver transplantation in childhood: the 5-year outcome

BACKGROUND: Because the results of short-term recombinant human growth hormone (rhGH) treatment in children with growth impairment after liver transplantation (LTx) have been promising, we have studied the long-term effects of rhGH on growth and graft function after LTx. METHODS: Indications for rhGH treatment were height standard deviation score (hSDS) below -2.0 or growth velocity SDS below 0 and LTx at least 18 months before inclusion. Eight growth-retarded children were treated with rhGH for more than 5 years. RESULTS: During the first year, median growth rate improved from 3.3 to 7.0 cm/year. In the second and third year, growth velocity remained high at 6.6 cm/year and 6.2 cm/year, respectively (P=0.008). In the fourth year, median growth velocity started to decline but still remained above baseline during the fifth year of treatment (4.2 cm/year). The median hSDS improved from -3.6 to -2.7. During the rhGH treatment, no acute rejection episodes were detected, and graft function remained stable in all except one patient. She was diagnosed with chronic rejection in the third year of rhGH treatment. The patient had elevated liver enzymes and abnormal liver function tests already before rhGH treatment. CONCLUSIONS: The efficacy of rhGH treatment is sustained after the first year in liver-transplant children with non-GH-deficient growth retardation. Because of a potential risk of side effects, close monitoring of these patients is required.