Randomised controlled trial of recombinant human growth hormone in prepubertal and pubertal renal transplant recipients. British Association for Pediatric Nephrology

Growth hormone in pediatric chronic kidney disease: more than just height

Recombinant human growth hormone therapy, which was introduced in the 1980s, is now routine for children with advanced chronic kidney disease (CKD) who are exhibiting growth impairment. Growth hormone usage remains variable across different centers, with some showing low uptake. Much of the focus on growth hormone supplementation has been on increasing height because of social and psychological effects of short stature. There are, however, numerous other changes that occur in CKD that have not received as much attention but are biologically important for pediatric growth and development. This article reviews the current knowledge about the multisystem effects of growth hormone therapy in pediatric patients with CKD and highlights areas where additional clinical research is needed. We also included clinical data on children and adults who had received growth hormone for other indications apart from CKD. Ultimately, having robust clinical studies which examine these effects will allow children and their families to make more informed decisions about this therapy.

Long-term Catch-up Growth and Risk Factors for Short Adult Height After Pediatric Liver Transplantation: A Retrospective Study

BACKGROUND

Children requiring liver transplantation generally have severe growth retardation. Recipients experience posttransplantation catch-up growth, although some show short adult heights. We aimed to determine decades-long catch-up growth trends and risk factors for short adult height following liver transplantation.

METHODS

We analyzed long-term height Z scores and risk factors for short adult height in a single-center retrospective cohort of 117 pediatric liver transplantation recipients who survived >5 y, with 75 of them reaching adult height.

RESULTS

Median age at transplantation was 1.3 y, and the most common primary diagnosis was biliary atresia (76.9%). Mean height Z scores pretransplantation and 1, 3, and 8 y after transplantation were -2.26, -1.59, -0.91, and -0.59, respectively. The data then plateaued until 20 y posttransplantation when mean adult height Z score became -0.88, with a median follow-up of 18.6 y. Nineteen recipients did not show any catch-up growth, and one quarter of recipients had short adult height (<5th percentile of the healthy population). Multivariate analysis identified old age (odds ratio, 1.22 by 1 y; P = 0.002), low height Z scores at transplantation (odds ratio, 0.46 by 1 point; P < 0.001), and posttransplantation hospital stay ≥60 d (odds ratio, 4.95; P = 0.015) as risk factors for short adult height. In contrast, prolonged steroid use after transplantation was not considered a significant risk factor.

CONCLUSIONS

Although tremendous posttransplantation catch-up growth was observed, final adult height remained inadequate. For healthy physical growth, liver transplantation should be performed as early as possible, before growth retardation becomes severe.

Efficacy and safety of recombinant human growth hormone therapy in pediatric intestinal transplant recipients

BACKGROUND

Recombinant human growth hormone (rhGH) is widely used to treat growth retardation in children. We aimed to examine the effect of rhGH therapy on growth and its impact on allograft function in children with growth retardation after intestinal transplant (IT).

METHODS

We retrospectively included children younger than 19 years who had received an IT with or without the liver, were diagnosed with growth retardation, and have received rhGH between January 2010 and January 2021. Changes in the patient's anthropometric parameters between baseline and various time points were compared using the paired t-test or Wilcoxon signed-rank test, as appropriate.

RESULTS

Seven patients (all males and prepubertal) received rhGH for the median duration of 2.3 years. The median age at rhGH start was 9.5 years. The median growth velocity z-score improved from -0.95 before treatment to 2.3 (p = .04) and 1.9 (p = .06) after 1 and 2 years of treatment, respectively. The median height-for-age z-score significantly improved from -3.4 at rhGH start to -1.3 (p = .005) at rhGH stop and remained above baseline at the last visit (-2.4, p = .002). The change in the first-year growth velocity was negatively correlated with the change in the second-year growth velocity (r = -.90, p = .04). No serious adverse effects or worsening allograft function were observed.

CONCLUSIONS

Severely growth retarded children after IT could benefit from rhGH treatment. A larger, longitudinal study would be warranted to monitor the long-term effect and safety of rhGH and examine predictors of growth response to rhGH therapy in these pediatric IT recipients.

Liver Transplant for Posthepatectomy Liver Failure in Hepatoblastoma

OBJECTIVES

Predicting the risk of posthepatectomy liver failure is important when performing extended hepatectomy. However, there is no established method to evaluate liver function and improve preoperative liver function in pediatric patients.

MATERIALS AND METHODS

We show the clinical features of pediatric patients who underwent living donor liver transplant for posthepatectomy liver failure in hepatoblastoma. The subjects were 4 patients with hepatoblastoma who were classified as Pretreatment Extent of Disease III, 2 of whom had distal metastasis (chest wall and lung).

RESULTS

Hepatic right trisegmentectomy was performed in 3 patients and extended left hepatectomy in 1 patient. The median alpha-fetoprotein level at the diagnosis of hepatoblastoma was 986300 ng/mL (range, 22500-2726350 ng/mL), and the median alpha-fetoprotein level before hepatectomy was 8489 ng/mL (range, 23-22500 ng/mL). The remnant liver volume after hepatectomy was 33.3% (range, 20% to 34.9%). Four patients had cholangitis after hepatectomy and progressed to posthepatectomy liver failure. The peak serum total bilirubin after hepatectomy was 11.4 mg/dL (range, 8.7-14.6 mg/dL). Living donor liver transplant was performed for these 4 patients with posthepatectomy liver failure, and they did not have a recurrence.

CONCLUSIONS

When the predictive remnant liver volume by computed tomography-volumetry before extended hepatectomy for patients with hepatoblastoma is less than 40%, the possibility of posthepatectomy liver failure should be recognized.

Linear Growth in Pediatric Kidney Transplant Population

Introduction: Growth retardation is one of the main complications of chronic kidney disease (CKD) in children and induces a negative impact on quality of life. Materials and Methods: Retrospective analysis of all consecutive patients younger than 18 years old who received a first KT in our center between 2008 and 2018. Results: 95 first KT recipients, median age at KT of 7.83 years. At the time of KT, 65.52% of males and 54.05% females showed normal height. After transplantation, linear growth improved from -1.53 at transplant to -1.37 SDS height at the last visit. We detected a different linear growth pattern according to patient age at KT. Children younger than 3 years old exhibited the most significant growth retardation at baseline and the greatest linear growth over time (-2.29 vs. -1.82 SDS height), whereas catch-up was not observed in older patients. Multivariate analysis showed that use of corticosteroids was negatively related to SDS height at 1 year after transplantation and final SDS height only was positively associated with SDS height at KT. 44.2 and 22.1% patients received rhGH treatment before and after KT. 71.88% patients reached adulthood with normal final height. Conclusions: In our study, pediatric KT recipients exhibited a normal height in more than half of cases at KT and in more than two thirds at the final adult height. Only children younger than 6 years old presented a relevant growth catch-up after KT. Treatment with rhGH was used before and after KT with significant improvement in height.

Clinical practice recommendations for growth hormone treatment in children with chronic kidney disease

Achieving normal growth is one of the most challenging problems in the management of children with chronic kidney disease (CKD). Treatment with recombinant human growth hormone (GH) promotes longitudinal growth and likely enables children with CKD and short stature to reach normal adult height. Here, members of the European Society for Paediatric Nephrology (ESPN) CKD–Mineral and Bone Disorder (MBD), Dialysis and Transplantation working groups present clinical practice recommendations for the use of GH in children with CKD on dialysis and after renal transplantation. These recommendations have been developed with input from an external advisory group of paediatric endocrinologists, paediatric nephrologists and patient representatives. We recommend that children with stage 3–5 CKD or on dialysis should be candidates for GH therapy if they have persistent growth failure, defined as a height below the third percentile for age and sex and a height velocity below the twenty-fifth percentile, once other potentially treatable risk factors for growth failure have been adequately addressed and provided the child has growth potential. In children who have received a kidney transplant and fulfil the above growth criteria, we recommend initiation of GH therapy 1 year after transplantation if spontaneous catch-up growth does not occur and steroid-free immunosuppression is not a feasible option. GH should be given at dosages of 0.045–0.05 mg/kg per day by daily subcutaneous injections until the patient has reached their final height or until renal transplantation. In addition to providing treatment recommendations, a cost-effectiveness analysis is provided that might help guide decision-making.

This Evidence-Based Guideline developed by members of the European Society for Paediatric Nephrology CKD-MBD, Dialysis and Transplantation working groups presents clinical practice recommendations for the use of growth hormone in children with chronic kidney disease on dialysis and after renal transplantation.

Growth hormone treatment improves final height and nutritional status of children with chronic kidney disease and growth deceleration

PURPOSE

Growth retardation is a common complication of chronic kidney disease (CKD) in children. Treatment with recombinant human growth hormone (rhGH) has been used to help short children with CKD to attain a height more in keeping with their age group, but the scientific evidence regarding the effect of rhGH on final height is scarce.

METHODS

Final heights of children with CKD receiving rhGH treatment (cases) were compared with final heights of a matched cohort of children with CKD that did not receive rhGH therapy (controls).

RESULTS

Sixty-eight rhGH-treated cases (44 boys) were compared with 92 untreated controls (60 boys). Mean duration of rhGH therapy was 4.2 ± 0.9 years; rhGH dose was 0.3 ± 0.07 mg/kg/week. Height SDS at baseline was lower in rhGH-treated patients than in controls (-2.00 ± 1.02 versus -0.96 ± 1.11, p < 0.001). Baseline height SDS was significantly lower than target height SDS in both groups. Height SDS significantly improved from baseline to final height attainment in rhGH-treated patients, while it slightly decreased in controls (mean SDS variation 0.69 ± 1.05 in rhGH-treated cases versus -0.15 ± 1.2 in controls). Final height SDS was -1.25 ± 1.06 in rhGH-treated cases and -1.06 ± 1.17 in controls (p = 0.29). Target adjusted final height SDS was -0.91 ± 1.03 in rhGH-treated cases and -0.61 ± 1.17 in controls (p = 0.1).

CONCLUSIONS

Long-term rhGH therapy is able to reduce the linear growth deceleration of children with CKD, and ultimately to improve their final height, reducing the difference with target height.

Near-adult height in male kidney transplant recipients started on growth hormone treatment in late puberty

BACKGROUND

Growth retardation and its impact on adult height is considered to be one of the most common complications in patients with chronic kidney disease (CKD). Treatment with recombinant human growth hormone (rhGH) has been effective in improving growth in kidney transplantation (KTx) patients, but little data are available on adult height in patients who began rhGh treatment in late puberty.

METHODS

Near-adult height was evaluated in 13 KTx patients treated with rhGH [growth hormone group (GHGr); dose 9.33 mg/m² per week] for a period of at least 18 months. At initiation of rhGH treatment, testicular volume was >8 ml and serum testosterone was >1 ng/ml compared with the control group (CGr) of ten KTx patients who did not receive rHGH. All subjects were of similar chronological age and bone age and had similar creatinine clearance (CrCl) levels, cumulative corticoid dose, height standard deviation score (SDS), target height SDS, and target height:initial height at the beginning of the study.

RESULTS

Near-adult height was significantly greater in the GHGr than in the CGr (-1.8 ± 0.8 vs. -2.9 ± 1.1; p = 0.018). The difference between initial height and near-adult height in the GHGr revealed a significant height gain (initial height -3.1 ± 1.1; near-adult height -1.8 ± 0.8 SDS, respectively; delta 1.2 ± 0.3; p = 0.021). The CrCl level was not significantly different between the GHGr and CGr at either at study initiation or when attaining near-adult height (p = 0.74 and p = 0.23, respectively).

CONCLUSIONS

Treatment with rhGH was effective in improving adult height in KTx patients who began treatment in late puberty, without any effect on renal function.

Growth hormone therapy in children with CKD after more than two decades of practice

This review focuses on the evidence for the efficacy and safety of recombinant human growth hormone (rhGH) therapy in children with all stages of chronic kidney disease (CKD) and at all ages. It describes the improving height prognosis for our patients both with and without rhGH; explains the underlying hormonal abnormalities that provide the rationale for rhGH use in CKD and the endocrine changes that accompany treatment; and views on who warrants treatment, with what dose, and how long for.

Growth, chronic kidney disease and pediatric kidney transplantation: is it useful to use recombinant growth hormone in Colombian children with renal transplant?

Kidney transplantation has become the best treatment for children with chronic kidney disease (CKD). In recent times, knowledge concerning the effect of CKD and kidney transplantation over the normal growth rate has increased; now it is known that 40% of children with CKD do not reach the expected height for age. Growth retardation has been associated with the type of nephropathy, metabolic and endocrine disorders that are secondary to kidney disease, immunosuppressive therapy with glucocorticoids, and suboptimal function of renal allograft. Nowadays, we know better the role of the growth hormone/insulin-like growth factor 1 axis in growth retardation we can see it in children with CKD or recipients of renal allograft. Several studies have shown that administration of recombinant growth hormone (rhGH) has a positive effect on the longitudinal growth of children and teenagers who have received a kidney transplant. On the other hand, there have been reported side effects associated with using rhGH; however, these are not statistically significant. In this article, we show a small review about growth in children with CKD and/or recipients of renal allografts the growth pattern of three children who were known by the Transplant Group of National University of Colombia, and the results obtained with the use of rhGH in one of these cases. We want to show the possibility of achieving a secure use of rhGH in children with CKD and its use as a therapeutic option for treating the growth retardation in children with kidney transplantation, and set out the need of typifying the growth pattern of Colombian children with CKD and/or who are recipients of renal allografts through multicenter studies to propose and analyze the inclusion of rhGH in the therapeutic scheme of Colombian children with these two medical conditions. rhGH could be a useful tool for treating children with CKD or kidney transplantation who have not reached the expected longitudinal growth for age. However, it is necessary to know the growth pattern standards for Colombian children with CKD or kidney transplant in Bogotá-Colombia to include the rhGH in clinical protocols for treatment of these patients.

Growth hormone, insulin-like growth factor-1, and the kidney: pathophysiological and clinical implications

Besides their growth-promoting properties, GH and IGF-1 regulate a broad spectrum of biological functions in several organs, including the kidney. This review focuses on the renal actions of GH and IGF-1, taking into account major advances in renal physiology and hormone biology made over the last 20 years, allowing us to move our understanding of GH/IGF-1 regulation of renal functions from a cellular to a molecular level. The main purpose of this review was to analyze how GH and IGF-1 regulate renal development, glomerular functions, and tubular handling of sodium, calcium, phosphate, and glucose. Whenever possible, the relative contributions, the nephronic topology, and the underlying molecular mechanisms of GH and IGF-1 actions were addressed. Beyond the physiological aspects of GH/IGF-1 action on the kidney, the review describes the impact of GH excess and deficiency on renal architecture and functions. It reports in particular new insights into the pathophysiological mechanism of body fluid retention and of changes in phospho-calcium metabolism in acromegaly as well as of the reciprocal changes in sodium, calcium, and phosphate homeostasis observed in GH deficiency. The second aim of this review was to analyze how the GH/IGF-1 axis contributes to major renal diseases such as diabetic nephropathy, renal failure, renal carcinoma, and polycystic renal disease. It summarizes the consequences of chronic renal failure and glucocorticoid therapy after renal transplantation on GH secretion and action and questions the interest of GH therapy in these conditions.

Growth in children with chronic kidney disease: role of nutrition, growth hormone, dialysis, and steroids

PURPOSE OF REVIEW

Children with chronic kidney disease (CKD) have impaired growth that leads to short stature in adulthood. The problem persists even with successful transplantation and steroid withdrawal protocols. The aim of this review is to provide an overview of the pressing issues related to growth failure in children with CKD both before and after transplantation.

RECENT FINDINGS

Although great strides have been made in dialysis and transplantation, the incidence of abnormal adult height in children growing up with CKD remains as high as 45-60%. The lack of catch-up growth and resultant short stature is a critical issue for self-esteem and quality of life in many children with CKD. Aggressive daily dialysis, improved nutrition, treatment of metabolic bone disease, and the use of recombinant human growth hormone provide some hope for catch-up growth in select patients.

SUMMARY

The causes of growth failure in the setting of CKD are multifactorial. Attention to all the details by optimizing nutritional, bone and mineral metabolism, correcting metabolic acidosis and anemia, achieving excellent blood pressure control, reversing cardiovascular complications such as left ventricular hypertrophy, and minimizing the use of corticosteroids is the current standard of care. Aggressive daily dialysis can reverse many of the uremic derangements. For patients not yet on dialysis or for those after renal transplant, early institution of recombinant human growth hormone can promote growth. Improved understanding of the mechanisms of hormone resistance may offer novel targets or measurements of treatment effectiveness.

Growth following solid organ transplantation in childhood

One of the ultimate goals of successful transplantation in pediatric solid organ transplant recipients is the attainment of optimal final adult height. This manuscript will discuss the attainment of height following solid organ transplantation in pediatric recipients of kidney, liver, heart, lung, and small bowel transplantation. Age is a primary factor with younger recipients exhibiting the greatest immediate catch up growth. Graft function is a significant contributory factor with a reduction in glomerular filtration rate correlating with poor growth in kidney recipients and the need for re-transplantation with impaired growth in liver recipients. The known adverse impact of steroids on growth has led to modification of steroid dosage and even to steroid withdrawal and steroid avoidance. In kidney and liver recipients, this has been associated with the development on occasion of acute rejection episodes. In infant heart transplantation, avoidance of maintenance corticosteroid immunosuppression is associated with normal growth velocity in the majority of patients. With marked improvement in patient and graft survival rates in pediatric organ graft recipients, it is timely that the quality of life issues, such as normal adult height, receive paramount attention. In general, normal growth post-transplantation should be an achievable goal that results in normal adult height for many solid organ transplantation recipients.

Growth following solid organ transplantation in childhood

One of the ultimate goals of successful solid organ transplantation in pediatric recipients is attaining an optimal final adult height. This manuscript will discuss growth following transplantation in pediatric recipients of kidney, liver, heart, lung or small bowel transplants. Remarkably similar factors impact growth in all of these recipients. Age is a primary factor, with younger recipients exhibiting the greatest immediate catch-up growth. Graft function is a significant contributing factor, with a reduced glomerular filtration rate correlating with poor growth in kidney recipients and the need for re-transplantation with impaired growth in liver recipients. The known adverse impact of steroids on growth has led to modification of the steroid dose and even steroid withdrawal and avoidance. In kidney and liver recipients, this strategy has been associated with the development of acute rejection. In infant heart transplantation, avoiding maintenance corticosteroid immunosuppression is associated with normal growth velocity in the majority of patients. With marked improvements in patient and graft survival rates in pediatric organ recipients, quality of life issues, such as normal adult height, should now receive paramount attention. In general, normal growth following solid organ transplantation should be an achievable goal that results in normal adult height.

Growth hormone treatment after renal transplantation: a promising but underused chance to improve growth

Growth retardation remains a clinical problem in children with chronic kidney disease (CKD) prior to and during end-stage renal disease. The growth of approximately 40 % of children on dialysis is stunted. Even so, growth hormone treatment (GH) is not used in the majority of small children prior to transplantation. Also, GH is effective in improving growth after transplantation, but again, it is only rarely used in this situation mainly for fear of triggering rejection episodes. In controlled studies, the number of patients who developed rejection episodes with GH was no greater than the number in untreated controls. However, patients with prior frequent rejection episodes developed further repeated subsequent rejection episodes. Many patients with repeated rejection episodes before GH treatment have reduced renal function and are expected to proceed to dialysis or retransplantation. We believe that in these patients, early individual decisions for or against GH treatment should be made as soon as other treatment strategies, such as steroid withdrawal, have failed or are not indicated. Decisions for GH treatment at a later pubertal age come too late for significant growth response and/or improvement of final height.

Growth hormone improves growth in pediatric renal transplant recipients--a systemic review and meta-analysis of randomized controlled trials

BACKGROUND

Growth hormone had been applied to treat pediatric renal allograft recipients with growth retardation. In this systemic review and meta-analysis, we assess the efficiency and safety of growth hormone use in post-renal transplant children.

METHODS

A literature search revealed five prospective randomized controlled trials assessing this therapy, with a total of 401 patients. The outcomes, including the baseline height standard deviation score (HSDS), HSDS after a 1-year therapy, delta height standard deviation score (△HSDS), allograft rejection rates and changes in the glomerular filtration rates (GFR) were analyzed.

RESULTS

Pooled data of the five studies showed that 1 year after the randomized controlled trials, the experimental group receiving growth hormone had a significantly higher growth velocity than the control group, with a mean HSDS difference of 0.68 [95 % confidence interval (CI) 0.25-1.11, P = 0.002] between the two groups. The mean difference in the △HSDS between the treated and control group was 0.52 (95 % CI 0.37-0.68, P < 0.00001). The rejection episode rates were 35/205 and 19/185, respectively (number of patients with rejection/ total number of patients) (risk ratio 1.56, 95 % CI 0.97-2.53, P = 0.07), and the mean difference in the △GFR was 3.27 ml/min per 1.73 m(2) (95 % CI -3.54-10.09, P = 0.35), which was not statistically significant.

CONCLUSIONS

Based on these studies, we suggest that the application of growth hormone is an effective treatment to promote the growth velocity of children after kidney transplantation. However, the safety of this treatment needs further evaluation.

Effectiveness of rhGH treatment on final height of renal-transplant recipients in childhood

BACKGROUND

Growth retardation is a considerable clinical problem in children with chronic kidney disease (CKD). Optimization of metabolic and nutritional parameters does not always lead to improved growth. Recombinant human growth hormone (rhGH) treatment has been used to improve height. Several studies in the literature have shown increased growth velocity, although data on the final height (FH) reached are scarce.

AIMS

We assessed the effect of rhGH on FH standard deviation score (SDS) in children with CKD following renal transplantation (RTx), comparing it with patients who did not receive rhGH (control group) but were treated with the same protocol and followed up in a single Center.

METHODS

Thirty-three patients received rhGH treatment until FH. Fourteen who refused rhGH therapy were included in the controls. Prognostic factors for FH and changes in glomerular filtration rate (GFR) during follow-up were also analyzed

RESULTS

FH SDS in rhGH-treated patients was significantly higher than in controls (-1.88 ± 1.14 vs -3.48 ± 1.19 SDS, respectively, p <0.05). In both groups, a similar reduction in GFR was observed. Height (SDS) at onset of rhGH treatment was the only statistically significant variable useful to predict response to treatment (p = 0.001).

CONCLUSION

Our findings confirm that rhGH is effective to improve FH in CKD RTx patients, without affecting kidney function.

Growth hormone for children with chronic kidney disease

BACKGROUND

Growth retardation is a common complication of chronic kidney disease (CKD) in children and is of concern to families. Recombinant human growth hormone (rhGH) treatment has been used to help short children with CKD attain a height more in keeping with their age group. However there are concerns about the long-term benefits of rhGH in significantly improving adult height as well as concerns about potential adverse effects (deterioration in native kidney function, increased acute rejection in kidney transplant recipients, benign intracranial hypertension).

OBJECTIVES

To evaluate the benefits and harms of rhGH treatment in children with CKD.

SEARCH METHODS

Randomised controlled trials (RCTs) were identified from the Cochrane Renal Group's Specialised Register, Cochrane Central Register of Controlled Trials (CENTRAL) (Issue 12, 2011), MEDLINE (from 1966), EMBASE (from 1980), article reference lists and through contact with local and international experts in the field.Date of last search: December 29, 2011

SELECTION CRITERIA

RCTs were included if they were carried out in children aged zero to 18 years, diagnosed with CKD, who were pre-dialysis, on dialysis or post-transplant; if they compared rhGH treatment with placebo/no treatment or two doses of rhGH treatments; and if they included height outcomes.

DATA COLLECTION AND ANALYSIS

Two authors independently assessed studies for risk of bias and extracted data from eligible studies. Data was pooled using a random effects model with calculation of mean difference (MD) for continuous outcomes with 95% confidence intervals (CI).

MAIN RESULTS

Sixteen studies (enrolling 809 children) were identified. Risk of bias assessment indicated that study quality was poor or poorly reported with only four and five studies respectively reporting adequate allocation concealment or blinding of study participants and investigators. Treatment with rhGH (28 IU/m²/wk) compared with placebo or no specific therapy resulted in a significant increase in height standard deviation score (HSDS) at one year (8 studies, 391 children: MD 0.82, 95% CI 0.56 to 1.07), and a significant increase in height velocity at six months (2 studies, 27 children: MD 2.85 cm/6 mo, 95% CI 2.22 to 3.48) and one year (7 studies, 287 children: MD 3.88 cm/y, 95% CI 3.32 to 4.44). Height velocity, though reduced, remained significantly greater than untreated children during the second year of therapy (1 study, 82 children: MD 2.30 cm/y, 95% CI 1.39 to 3.21). Compared to the 14 IU/m²/wk group, there was a 1.18 cm/y increase in height velocity in the 28 IU/m²/wk group (3 studies, 150 children: 1.18 cm/y, 95% CI 0.52 to 1.84) . The frequency of reported side effects of rhGH was generally similar to that of the control group.

AUTHORS' CONCLUSIONS

One year of 28 IU/m²/wk rhGH in children with CKD resulted in a 3.88 cm increase in height velocity above that of untreated patients. Studies were too short to determine if continuing treatment resulted in an increase in final adult height.

The role and future challenges for recombinant growth hormone therapy to promote growth in children after renal transplantation

Chronic kidney disease can severely impair linear growth in children. For many children, growth improves after renal transplantation, but for some, growth velocity remains low and for others, catch-up growth is insufficient to compensate for the deficit imparted by renal disease in the preceding years. Inadequate final adult height after renal transplant is multifactorial and can adversely affect the quality of life (QOL), psychosocial development and long term prospects for these children as they grow into adulthood. Growth failure after renal transplant requires thorough evaluation and its management in renal transplant recipients can involve improved nutritional intake, correction of metabolic acidosis, treatment of secondary hyperparathyroidism, steroid-sparing immunosuppression and/or use of recombinant human growth hormone (rGH). Treatment with rGH after renal transplant has been evaluated by a limited number of clinical trials suggesting efficacy and safety for this treatment strategy. Several important clinical questions regarding rGH use in children post-renal transplant remain unanswered.

Effects of steroid avoidance and novel protocols on growth in paediatric renal transplant patients

The vast majority of kidney transplant recipients undergo triple maintenance immunosuppression that includes the use of steroids. Irrespective of their long history in organ transplantation and proven efficacy in preventing acute graft rejection, steroids exhibit an unfavourable toxicity profile, including growth retardation in children. Given these negative effects, therapeutic approaches that will substantially decrease patients' exposure to steroids have been considered. The planned approaches included alternate day administration, rapid or late steroid withdrawal at the pre-scheduled time after transplantation and complete steroid avoidance. All three of these strategies have been tested in single- or multicentre studies and shown to have distinct clinical advantages in terms of decreasing the incidence and severity of specific adverse events. However, the safety of these protocols could not be universally proven. The Stanford study showed that a complete steroid avoidance under the "cover" of tacrolimus, mycophenolate mofetil and extended daclizumab induction is a very effective regimen for obtaining an improvement in post-transplantation growth. The recently reported international randomized TWIST trial demonstrated growth improvement as early as 6 months post-transplantation. These protocols may potentially enable paediatric renal graft recipients to safely avoid steroid exposure.

What have 20 years of data from the North American Pediatric Renal Transplant Cooperative Study taught us about growth following renal transplantation in infants, children, and adolescents with end-stage renal disease?

Growth following renal transplantation in infants, children, and adolescents was evaluated from 20 years of data reported to the registry of the North American Pediatric Renal Transplant Cooperative Study (NAPRTCS). The analysis of more than 10,000 recipients addressed the following questions: 1. What is the impact of age, pubertal growth, gender, transplant history, donor source and allograft function on growth after transplantation? 2. Has the height Z score at the time of transplantation changed during the past two decades and has this influenced final adult height? 3. To what extent has recombinant human growth hormone (rhGH) been utilized in growth retarded recipients after transplantation and has its use resulted in accelerated post-transplantation growth? 4. Has the use of steroids for maintenance immunosuppression changed over the past 20 years and how have the perturbations of steroid usage influenced post-transplantation growth? 5. Have changes in clinical care resulted in improved final adult height Z score during the past two decades? Only younger children (<6 years) had initial accelerated post-transplantation growth. The mean increment in height during puberty was 18.8 cm (21.7 cm in 4.7 years for boys and 14.3 cm in 4.5 years for girls). Gender, source of donor graft, or number of grafts did not influence growth. Height Z score at transplantation has improved over the past two decades, as has final adult height with each succeeding era. The use of rhGH after transplantation results in a delta Z score of +0.5 standard deviation (SD). Post-transplantation growth improves with steroid avoidance and changes in estimated glomerular filtration rate (eGFR) impact on growth.

Etiology and treatment of growth retardation in children with chronic kidney disease and end-stage renal disease: a historical perspective

Dramatic changes have occurred in our understanding of the etiology of the growth retardation associated with chronic kidney disease (CKD) and end-stage renal disease (ESRD) during the past 50 years. Significant interest has been focused on preventing and/or correcting the growth retardation because of the emergence of the dual therapeutic modalities of dialysis and renal transplantation to prolong the lives of infants, children, and adolescents afflicted with CKD and ESRD. These efforts have resulted in a significant improvement in the height Z-score over the past two decades of children with CKD and ESRD. This has had a salutary impact on the final adult height of such children which should hopefully lead to an enhanced quality of life in the future. This report addresses the progress that has been made in the management of growth retardation in the pediatric population with CKD and ESRD.

Approach to optimizing growth, rehabilitation, and neurodevelopmental outcomes in children after solid-organ transplantation

One of the most critical differences between the posttransplant care of children and adults is the requirement in children to maintain a state of health that supports normal physical and psychological growth and development. Most children with organ failure have some degree of growth failure and developmental delay, which is not quickly reversed after successful transplantation. The challenge for clinicians caring for these children is to use strategies that minimize these deficits before transplantation and provide maximal opportunity for recovery of normal developmental processes during posttransplant rehabilitation. The effect of chronic organ failure, frequently complicated by malnutrition, on growth potential and cognitive development is poorly understood. This review presents a summary of what is known regarding risk factors for suboptimal growth and development following solid-organ transplant and describe possible strategies to improve these outcomes.

KDIGO clinical practice guideline for the care of kidney transplant recipients

The 2009 Kidney Disease: Improving Global Outcomes (KDIGO) clinical practice guideline on the monitoring, management, and treatment of kidney transplant recipients is intended to assist the practitioner caring for adults and children after kidney transplantation. The guideline development process followed an evidence-based approach, and management recommendations are based on systematic reviews of relevant treatment trials. Critical appraisal of the quality of the evidence and the strength of recommendations followed the Grades of Recommendation Assessment, Development, and Evaluation (GRADE) approach. The guideline makes recommendations for immunosuppression, graft monitoring, as well as prevention and treatment of infection, cardiovascular disease, malignancy, and other complications that are common in kidney transplant recipients, including hematological and bone disorders. Limitations of the evidence, especially on the lack of definitive clinical outcome trials, are discussed and suggestions are provided for future research.

Growth failure associated with sirolimus: case report

An 11-year-old girl, who was a renal transplant recipient, developed linear growth failure associated in time with sirolimus (SRL) treatment. After 5 years of functional graft [creatinine clearance (CCr) 90 ml/min per 1.73 m(2) body surface area], she developed acute renal failure due to calcineurin inhibitor-related hemolytic uremic syndrome, and cyclosporine A was replaced by SRL. Before the drug change, she had been growing normally (5.5 cm/year) and had reached the 33.9 percentile (P) of height (z-height -0.41), similar to her target. Two years later, her height had decreased to P 6th (z-height -1.54), as her growth velocity had diminished to 2.2 cm/year, despite optimal renal function (CCr 68 ml/min per 1.73 m(2)). Human recombinant growth hormone was needed to promote her catch-up growth and achieve the P 49th of height (z-height -0.03). SRL may have deleterious effects on growing children due its characteristic anti-proliferative and anti-angiogenic properties. Pediatric transplant recipients' linear growth should be cautiously monitored while they are being given SRL.

Growth after renal transplantation

Growth may be severely impaired in children with chronic renal insufficiency. Since short stature can have major consequences on quality of life and self-esteem, achieving a 'normal' height is a crucial issue for renal transplant recipients. However, despite successful renal transplantation, the final height attained by most recipients is not the calculated target height. Catch-up growth spurts post-transplantation are usually insufficient to compensate for the retardation in growth that has occurred during the pre-transplant period. Longitudinal growth post-transplantation is therefore influenced by the age at transplantation but also by subsequent allograft function and steroid exposure, both of which interfere with the growth hormone/insulin-like growth factor axis. The management of growth retardation in renal transplant recipients includes adequate nutritional intake, correction of metabolic acidosis, prevention of bone disease, steroid-sparing strategies and a supraphysiological dose of recombinant human growth hormone in selected cases.

Growth hormone treatment started in the first year of life in infants with chronic renal failure

Infants with chronic renal failure (CRF) are at high risk of experiencing severe growth retardation. We report a study of 12 infants with CRF who have been treated with recombinant human growth hormone (rhGH) since the age of 0.5 +/- 0.3 years. A control group comprised 15 infants with less severe CRF who were being treated during the same period, but who did not receive rhGH. Despite the infants in the rhGH group had more severe renal failure, they grew at least as well as those in the control group and experienced catch-up growth that started earlier and was more sustained; they also gained more weight. Between the age of 0.5 and 2.5 years, the height standard deviation score (HtSDS) improved from -2.0 +/- 1.2 to -0.9 +/- 0.9 in the rhGH group (p < 0.005) and from -1.6 +/- 1.6 to -1.0 +/- 1.9 in the control group (p=non significant, n.s.). The average gain in HtSDS was +1.1 +/- 0.8 in the treated group and +0.6 +/- 1.4 in the control group (p = n.s.). During the same period, the weight SDS improved from -2.2 +/- 0.9 to -0.6 +/- 1.2 (p < 0.005) and from -1.9 +/- 1.2 to -1.3 +/- 1.2 (p=n.s.) in the treatment and control groups, respectively. Nutritional intake was similar in both groups, while parathyroid hormone levels tended to increase, although not significantly, after rhGH treatment (p=n.s.). The results of this pilot study suggest that very early treatment with rhGH in patients with early-onset CRF may improve growth.

Recombinant growth hormone use pretransplant and risk for post-transplant lymphoproliferative disease--a report of the NAPRTCS

rhGH, widely used to optimize linear growth in children with ESRD, also modulates B-cell precursor development and may be associated with malignancy development. To determine if rhGH use in children was associated with higher risk of PTLD, we analyzed retrospectively collected data on children with CRI, on dialysis or with renal transplants in a large multi-center registry of children with ESRD. Of the 194 LPD patients currently listed in the registry, 41 were previously enrolled in the CRI registry and 18/41 (43.9%) used rhGH during their period with CRI. Among CRI patients who later received a transplant, rates of PTLD post-transplant were significantly higher among rhGH users (18/407 or 4.4%) compared to patients who never used rhGH during their CRI follow-up and received a transplant (23/1240 or 1.9%, p = 0.009). After adjusting for the confounders of recipient age (at CRI and at transplant) and transplant era, the use of rhGH pretransplant was associated with a borderline higher risk for PTLD (odds ratio 1.88, 95% CI = 1.00-3.55, p = 0.05). In contrast, use of rhGH during dialysis or post-transplant only was not associated with a higher risk for PTLD. Continued monitoring is recommended.

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.

Management of growth retardation in pediatric recipients of renal allografts

Growth retardation frequently accompanies chronic kidney disease in children. Unfortunately, this retardation persists in magnitude despite assiduous therapeutic efforts, adequate dialytic intervention, and successful transplantation. The age of the patient at transplantation, allograft function, and corticosteroid dosage are the major factors that contribute to persistent suboptimal growth following renal transplantation. Recent data indicate that the use of recombinant human growth hormone might efficaciously improve growth velocity in the persistently growth-retarded allograft recipient. Attainment of optimum final adult height is predicated on optimum height at the time of transplantation, persistent optimum allograft function, minimization or avoidance of corticosteroid treatment, and, possibly, use of recombinant human growth hormone, especially to potentially maximize the pubertal growth spurt.

Growth after organ transplantation

Growth is an important feature of childhood, but it is usually impaired before and after organ transplantation. Modest catch-up growth often occurs after renal transplantation. Nevertheless, patients remain short due to the effects of steroids used for immunosuppression. Children with chronic liver failure are also growth impaired, although not to the same extent. They also frequently have poor catch up growth after transplantation, again due to steroids. There are several randomized controlled clinical trials reporting growth hormone (GH) use after renal transplantation. These consistently show a beneficial effect of GH on linear growth. Patients with histories of frequent acute rejections before GH may have increased risk of acute rejection during treatment. Few data exist on liver transplant patients, although GH also appears effective. GH use may be safe and effective for renal transplant recipients who have been stable without acute rejection episodes. There needs to be long-term study of GH use in liver and renal transplant patients. It is critical to focus efforts on improving growth in renal failure before transplantation through GH use and to improve posttransplant growth in all recipients by minimizing steroid exposure.

Growth hormone for children with chronic kidney disease

BACKGROUND

Chronic kidney disease (CKD) is an uncommon but important condition. Growth retardation, one of the complications of CKD, is of concern to families. Recombinant human growth hormone (rhGH) treatment has been used to help short children with CKD attain a height more in keeping with their age group. However, there are concerns that rhGH may have an adverse effect on the preservation of native kidney function, predispose to acute rejection in kidney transplant recipients, and cause benign intracranial hypertension and slipped capital femoral epiphysis.

OBJECTIVES

To evaluate the benefits and harms of rhGH treatment in children with CKD.

SEARCH STRATEGY

Randomised controlled trials (RCTs) were identified from the Cochrane Central Register of Controlled Trials (CENTRAL), MEDLINE, EMBASE, article reference lists and through contact with local and international experts in the field. Date of most recent search: July 2005

SELECTION CRITERIA

RCTs were included if they were carried out in children aged 0-18 years, diagnosed with CKD, who were pre-dialysis, on dialysis or post-transplant; if they compared rhGH treatment with placebo/no treatment or two doses of rhGH treatments; and if they included height outcomes.

DATA COLLECTION AND ANALYSIS

Two reviewers independently assessed studies for methodological quality and extracted data from eligible trials. Data was pooled using a random effects model with calculation of weighted mean difference (MD) for continuous outcomes and relative risk (RR) for categorical outcomes with 95% confidence intervals (CI).

MAIN RESULTS

Fifteen RCTs (629 children) were identified. Treatment with rhGH (28 IU/m(2)/wk) resulted in a significant increase in height standard deviation score (SDS) at one year (MD 0.78 SDS, 95% CI 0.52 to 1.04), and a significant increase in height velocity at six months (MD 2.85 cm/6 mo, 95%CI 2.22 to 3.48) and one year (MD 3.80 cm/y, 95%CI 3.20 to 4.39). Compared to the 14 IU/m(2)/wk group, there was a 1.34 cm/y (0.55 to 2.13) increase in height velocity in the 28 IU/m(2)/wk group. The frequency of reported side effects of rhGH were similar to that of the control group.

AUTHORS' CONCLUSIONS

One year of 28 IU/m(2)/wk rhGH in children with CKD resulted in a 3.80 cm/y increase in height velocity above that of untreated patients. Trials were too short to determine if continuing treatment resulted in an increase in final adult height.

Longitudinal growth in children following kidney transplantation: from conservative to pharmacological strategies

Impairment of longitudinal growth in children with chronic renal failure (CRF) is multifactorial. It is mainly due to disturbances in the growth hormone (GH)/insulin-like growth factor (IGF)/IGF-binding protein axis. Growth failure can be managed by optimizing nutrition and fluid/electrolyte homeostasis, and overcoming the growth-inhibiting effects of uremia by high-dose recombinant human (rh) GH treatment. A sufficient catch-up growth is one of the determining issues for the overall success of pediatric kidney transplantation (Tx). However, despite satisfactory renal function, spontaneous catch-up growth is often insufficient as glucocorticoid treatment is the main inhibiting factor for longitudinal growth after Tx. In addition, longitudinal growth may be jeopardized by low glomerular filtration rate (GFR) and African American or Hispanic background. Supraphysiological doses of GH and/or IGF-I in vitro and in vivo can partially overcome the growth-inhibiting effects of glucocorticoid treatment. GH-associated increase of leukocyte proliferation and cytotoxicity with stimulated interferon synthesis have been demonstrated. However, it is not clear whether such stimulatory effects on leukocyte function are a transitory or a constant risk factor after organ Tx. Clinical trials of GH in children after renal Tx have suggested a rather moderate or transient effect of rhGH on the immune system, and corticosteroids induce a hyporesponsiveness to the action of GH. As long as corticosteroids are believed to be essential after renal Tx, rhGH should be considered to optimize longitudinal growth in children.

Assessment and treatment of short stature in pediatric patients with chronic kidney disease: a consensus statement

Growth failure is a clinically important issue in children with chronic kidney disease (CKD) and is associated with significant morbidity and mortality. Many factors contribute to impaired growth in these children, including abnormalities in the growth hormone (GH)-insulin-like growth factor-I (IGF-I) axis, malnutrition, acidosis, and renal bone disease. The management of growth failure in children with CKD is complicated by the presence of other disease-related complications requiring medical intervention. Despite evidence of GH efficacy and safety in this population, some practitioners and families have been reluctant to institute GH therapy, citing an unwillingness to comply with daily injections, reimbursement difficulties, or impending renal transplantation. Suboptimal attention to growth failure management may be further compounded by a lack of clinical guidelines for the appropriate assessment and treatment of growth failure in these children. This review of growth failure in children with CKD concludes with an algorithm developed by members of the consensus committee, outlining their recommendations for appropriate steps to improve growth and overall health outcomes in children with CKD.

Special issues in pediatric kidney transplantation

Pediatric and adult kidney transplantation differ in many ways, but one of the most significant differences is the impact of kidney disease and kidney transplantation on growth and development in pediatric patients. Multiple facets of transplantation may have an impact on growth and development, including the timing of transplantation, choice of immunosuppressive agents, and the presence of hypertension. In addition, graft function has a significant impact on linear growth, and so preservation of function becomes important not only for general health and quality of life but also for optimizing growth. Other concerns in pediatric kidney transplantation include a heightened risk for posttransplantation infectious complications, including lymphoproliferative disease. In addition, the impact of immunosuppressive drugs on adherence to therapy is important. Although adherence is a complex and multifactorial process, immunosuppressive drugs that cause physical side effects may contribute to drug nonadherence because children, and particularly adolescents, may be inclined to stop taking medications associated with physical changes that differentiate them from their peers. Studies that further delineate factors that affect growth and development, risk for infectious complications, and nonadherence will be important to maximize outcomes in pediatric kidney transplantation.

Corticosteroid avoidance in pediatric renal transplantation

Corticosteroids have played a central role in the evolution of renal transplant as the modality of choice for renal replacement in end stage kidney disease. Their use is associated with significant, dose related morbidity including osseous, cardiovascular, metabolic complications, body disfigurement and growth retardation in children. The strategies that have been employed to minimize these side effects include reduction in the daily administered dose of steroids, use of alternate day dosing regimens, steroid withdrawal post-transplantation and complete steroid avoidance. Steroid dose minimization has been associated with increased rates of acute rejection, though introduction of newer and more potent immunosuppressives has helped reduce the incidence of this complication. Steroid minimization will benefit patient morbidity due to cataracts, cardiovascular and osseous complications, but may offer little benefit towards improving linear growth. Alternate day steroid therapy may have a greater impact on growth improvement, but may be troubled by regimen non-adherence. Steroid withdrawal post-transplant, the ultimate target, is successful in a cohort of patients, but overall, has been historically associated with unacceptably high rates of clinical acute rejection, and has thus been used sparingly in adults and even less so in children. Complete corticosteroid avoidance, using newer induction and immunosuppressive agents, has been associated with an 8-23% incidence of acute rejection in pediatric renal transplant patients, significant catch-up growth post-transplant, improvements in post-transplant hypertension and hyperlipidemia, and a high safety profile at current follow-up. Newer induction protocols may allow complete steroid-free immunosuppression thus offering significant advantages in preventing the above-mentioned steroid related morbidity, which could also possibly be applicable to other areas of solid organ transplantation in all age groups.

Long-term use of recombinant human growth hormone in pediatric allograft recipients: a report of the NAPRTCS Transplant Registry

Data from the NAPRTCS database were analyzed for growth, allograft function, and targeted adverse events (AE) over a 5-year period in 513 recipients who received recombinant human growth hormone (rhGH) treatment and compared with the outcome of 2,263 concurrent controls who did not receive rhGH. Recipients less than 10 years of age grew better than older recipients. Final adult height was superior in the rhGH-treated group compared with the control group. Allograft function and graft failure rate was similar in the rhGH-treated and control groups. No increased incidence of AE was noted in the rhGH-treated group. rhGH is effective and safe for use in growth-retarded pediatric renal allograft recipients.

Corticosteroid avoidance in pediatric renal transplantation: can it be achieved?

Corticosteroids have been a cornerstone therapy in renal transplantation, which is the treatment modality of choice for adult and pediatric end-stage renal disease. Their use is associated with significant morbidity, notably cardiovascular, endocrine, and bone complications, body disfiguration, and almost universal growth retardation in children. While newer immunosuppressants have reduced the incidence of these adverse effects, they continue to pose significant post-transplant challenges. There are various strategies that can be used to avoid these adverse effects including the use of an alternative corticosteroid such as deflazacort, minimization of corticosteroid dosage, corticosteroid withdrawal after a period of early use, and more recently complete corticosteroid avoidance. Recent randomized studies have demonstrated significant improvement in growth parameters, lipid profile, and in the amount of bone loss in patients treated with deflazacort, an oxazoline analog of prednisone, compared with methylprednisone.Corticosteroid minimization has been associated with an increased rate of acute rejection. While augmentation with newer immunosuppressants has helped reduce the incidence of acute rejection, significant improvements in growth have not been demonstrated. Alternate-day corticosteroid therapy has been shown to have a beneficial effect on growth but regimen compliance has limited its widespread applicability. Studies of corticosteroid withdrawal have met with varied success. Early corticosteroid withdrawal has been associated with rejection rates ranging from 10% to 81% and late corticosteroid withdrawal, from 13% to 68.8%, with acute rejection episodes occurring as late as 4 years after corticosteroid withdrawal. The rates of clinical acute rejection have been unacceptably high, and corticosteroid withdrawal is thus used very sparingly in adults and even less so in children. Complete corticosteroid avoidance as reported by an initial study has been associated with a 23% incidence of acute rejection and 'catch-up' growth post-transplantation in 14 pediatric recipients, as measured by the change in height standard deviation scores post-transplantation. A second renal transplant study, in adults, demonstrated similar rejection rates of 25% with improvement in post-transplant hypertension and lipid profiles. A more recent pediatric study using a novel extended daclizumab induction protocol demonstrated an 8% incidence of clinical acute rejection with significant improvements in graft function, hypertension, and growth, without an increased incidence of infectious complications. Renal transplantation with a corticosteroid-free protocol may offer significant advantages in the incidence of acute rejection, graft function, growth, blood pressure, lipidemia, and body appearance and appears to be well tolerated when used with a variety of current induction protocols to replace early corticosteroid use. This protocol may also be applicable to other areas of solid organ transplantation in all age groups.

Longitudinal Analysis of T???Helper Cell Phenotypes in Renal-Transplant Recipients Undergoing Growth Hormone Therapy

BACKGROUND

Treatment with recombinant human growth hormone (rhGH) in growth-retarded children after renal transplantation is effective, but there have been concerns regarding the safety of rhGH because of its possible immunomodulatory actions. We therefore evaluated the immune phenotypes of pediatric renal-transplant recipients and controls in response to rhGH with regard to a possible shift toward a T-helper (TH)1-type response.

METHODS

Intracellular cytokines, activation markers, costimulatory, and adhesion molecules were studied in 13 children after renal transplantation (Tx+GH). Children with chronic renal failure (CRF+GH, n=11) before and under rhGH therapy and pediatric renal-transplant recipients without rhGH therapy (Tx, n=33) served as controls. Measurements were performed by four-color flow cytometry before and 4, 12, 18 and 24 weeks after initiation of rhGH therapy.

RESULTS

Under baseline conditions, Tx+GH patients did not differ from Tx patients. During rhGH therapy in children with transplants, interleukin (IL)-2 production increased threefold at 4 weeks, and IL-4 and IL-13 increased by 70% at 12 weeks. All three cytokines returned to baseline after 18 weeks. No patient experienced rejection. In CRF+GH patients, baseline values for all investigated cytokines were higher than in patients with transplants but did not change in response to rhGH therapy.

CONCLUSION

Our data indicates that rhGH therapy in stable, pediatric renal-transplant recipients has a mild and transient immunostimulatory effect in vivo. Immunosuppression and graft function in patients with transplants undergoing rhGH treatment should therefore carefully be monitored.

Osseous complications of pediatric transplantation

Adult stature and peak bone mass are achieved through childhood growth and development. Multiple factors impair this process in children undergoing solid organ transplantation, including chronic illness, pretransplant osteodystrophy, use of medications with negative impact on bone, and post-transplant renal dysfunction. While growth delay and short stature remain common, the most severe forms of transplant-related bone disease, fracture and avascular necrosis, appear to have become less common in the pediatric age group. Osteopenia is very prevalent in adult transplant recipients and probably also in pediatrics, but its occurrence and sequelae are difficult to study in these groups due to methodological shortfalls of planar densitometry related to short stature and altered patterns of growth and development. Although the effect on lifetime peak bone mass is not clear, data from adult populations suggest an elevated long-term risk of bone disease in children receiving transplants. Optimal management of pretransplantation osteodystrophy, attention to post-transplant renal insufficiency among both renal and non-renal transplant patients, reduction of steroid dose in select patients, and supplementation with calcium plus vitamin D during expected periods of maximal bone loss may improve bone health. Careful research is required to determine the role of bisphosphonate therapy in pediatric transplantation.

Pediatric transplantation of the kidney, liver and heart: summary report

The following is a summary report of an extensive review of the literature from 1966 to 2001 on growth and development in children receiving kidney, liver and heart transplants. The literature was assessed for relevancy to current clinical practice and for reliability and generalizability of the inferences based on the study design, controls, sample size, age distribution, confounding factors, use of standardized instruments, and consistency with other findings. While studies on growth are included in the review, the main emphasis is on research in cognitive and psychosocial development since these areas have been far less thoroughly studied and contain various methodological deficiencies. On the basis of the literature review both general methodological recommendations and specific recommendations for future research studies are made. Access to the full is provided on the World Wide Web at http://light.emmes.com/pedstransplantation/.

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 (Delta=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.

Growth hormone therapy before and after pediatric renal transplant

Children undergoing successful renal transplantation anticipate optimal growth and development. The use of rhGH pre- and post-Tx has been evaluated and supported by randomized control trials. Several strategies are required to maximize the potential benefit of this treatment in the renal population including provision of adequate nutrition intake, following bone parameters with appropriate interventions, and strategies to reduce steroid therapy including utilization of alternate day steroid treatment. Studies are required to further assess the impact of rhGH on renal allograft function, rejection risk, and allograft ultrastructural changes.

Current status of kidney transplant: update 2003

Pediatric transplantation has seen remarkable advances over the past two decades with reduced morbidity and mortality, reduced rejection rates, and improved long-term patient and allograft survival. Infants currently have short-term patient and allograft survival rates better than any other age group; short-term allograft survival rates in CD recipients are equal to those in LD recipients. With decreased rejection, long-term allograft survival is improving dramatically. Transplantation allows for much reduced risks and improved metabolic status, growth and development, and more normal social interactions. The future of transplantation continues to be exciting, with opportunities for reduced immunosuppressive medications and their side effects, and the elusive goal of transplantation tolerance seems within reach.