Heather Maxwell

A Randomized Trial to Assess the Impact of Early Steroid Withdrawal on Growth in Pediatric Renal Transplantation: The TWIST Study

Minimizing steroid exposure in pediatric renal transplant recipients can improve linear growth and reduce metabolic disorders. This randomized multicenter study investigated the impact of early steroid withdrawal on mean change in height standard deviation score (SDS) and the safety and efficacy of two immunosuppressive regimens during the first 6 months after transplantation. Children received tacrolimus, MMF, two doses of daclizumab and steroids until day 4 (TAC/MMF/DAC, n=98) or tacrolimus, MMF and standard‐dose steroids (TAC/MMF/STR, n=98). Mean change in height SDS was 0.16 ± 0.32 with TAC/MMF/DAC and 0.03 ± 0.32 with TAC/MMF/STR. The mean treatment group difference was 0.13 (p < 0.005 [95% CI 0.04–0.22]), 0.21 in prepubertal (p = 0.009 [95% CI 0.05–0.36]) and 0.05 in pubertal children (p = ns). Frequency of biopsy‐proven acute rejection was 10.2%, TAC/MMF/DAC, and 7.1%, TAC/MMF/STR. Patient and graft survival and renal function were similar. Significantly greater reductions in total cholesterol and triglycerides but significantly higher incidences of infection and anemia were found with TAC/MMF/DAC (p < 0.05 all comparisons). Early steroid withdrawal significantly aided growth at 6 months more so in prepubertal than pubertal children. This was accompanied by significantly better lipid and glucose metabolism profiles without increases in graft rejection or loss.

Disparities in Policies, Practices and Rates of Pediatric Kidney Transplantation in Europe

We aimed to provide an overview of kidney allocation policies related to children and pediatric kidney transplantation (KTx) practices and rates in Europe, and to study factors associated with KTx rates. A survey was distributed among renal registry representatives in 38 European countries. Additional data were obtained from the ESPN/ERA‐EDTA and ERA‐EDTA registries. Thirty‐two countries (84%) responded. The median incidence rate of pediatric KTx was 5.7 (range 0−13.5) per million children (pmc). A median proportion of 17% (interquartile range 2−29) of KTx was performed preemptively, while the median proportion of living donor KTx was 43% (interquartile range 10−52). The median percentage of children on renal replacement therapy (RRT) with a functioning graft was 62%. The level of pediatric prioritization was associated with a decreased waiting time for deceased donor KTx, an increased pediatric KTx rate, and a lower proportion of living donor KTx. The rates of pediatric KTx, distribution of donor source and time on waiting list vary considerably between European countries. The lack of harmonization in kidney allocation to children raises medical and ethical issues. Harmonization of pediatric allocation policies should be prioritized.

Sorbitol-fermenting Escherichia coli O157, Scotland.

To the Editor: Verotoxin-producing Escherichia coli (VTEC) of serogroup O157 causes severe gastrointestinal and renal illness; clinical signs may be mild diarrhea, hemorrhagic colitis, or hemolytic uremic syndrome (HUS). Typically, 10%–15% of reported VTEC infections quickly progress to HUS (1). Sorbitol-fermenting (SF)–O157 strains have emerged in continental Europe (2,3). Some evidence suggests that SF-O157 is more frequently associated with HUS than are non-sorbitol–fermenting strains (3–6). SF-O157 shows increased adherence to colonic epithelial cells and may in turn cause a more potent inflammatory host response, resulting in a higher risk for HUS (4). The potentially greater virulence of SF-O157 requires urgent identification of its reservoir(s) and vehicle(s) of infection, as well as determination of genetic or other predisposing factors for infection with this strain. To understand whether the host pathophysiologic responses to SF-O157 and non–SF-O157 strains differ, we analyzed a cohort of children with HUS who were infected with E. coli O157. During April and May 2006, Health Protection Scotland (HPS) identified 18 cases of verotoxin-producing SF-O157 infection in Scotland, 13 of which were associated with a nursery. HUS developed in 8 of the 18 patients; those with thrombotic microangiopathy were admitted to the renal unit of a specialist pediatric hospital, which immediately reports cases of HUS to HPS as part of national surveillance (7). To test the hypothesis that SF-O157 was more virulent than non–SF-O157, we performed an age-matched, nested case–case study of HUS case-patients and analyzed host clinical markers, treatment, and outcomes from SF-O157 and non–SF-O157 cases in 2006. Clinical questionnaires, patient information sheets, and consent forms were completed by clinicians for each case-patient and returned to HPS; data were entered into a database in Epi Info version 6 (Centers for Disease Control and Prevention, Atlanta, GA, USA). Statistical analysis by t test showed that nadirs for serum albumin were significantly higher for children with SF-O157 HUS (p = 0.03; Table) than for children with non–SF-O157 HUS and that children with SF-O157 HUS had significantly more sessions of hemodialysis than did children with non–SF-O157 HUS (p = 0.01; Table). All case-patients were oligoanuric; the 2 groups did not differ with respect to this parameter. Initial signs and symptoms were similar for both sets of patients, i.e., classic VTEC symptoms of bloody diarrhea and abdominal pain. This finding is in acccordance with those of other studies of SF-O157 outbreaks, which also noted signs and symptoms compatible with VTEC-associated gastroenteritis (5,6). Table Characteristics of patients infected with non–SF-O157 versus SF-O157 Escherichia coli, Scotland, 2006* Our study highlights a number of lessons. Medical practitioners rarely have the opportunity to recognize patients at such an appreciable and predictable risk of progressing rapidly to anuric renal failure as they do when they see children with early O157 infection. Failure to appreciate the potential gravity of O157 infection and the possible development of HUS may result in avoidable illness and even death. Our investigation of the prehospital management of SF-O157 and non–SF-O157 in this cohort found no difference in pharmacologic intervention or duration of delay in admission to hospital. Our study has limitations. A number of patients in the cohort were prescribed antimicrobial drugs and/or antimotility drugs or were sent home from the local hospital without hospital admission or further monitoring; such actions potentially exacerbate clinical outcomes (1,8). We recognize that comparison of the SF-O157 outbreak strain with non–SF-O157 strains (some of which caused sporadic cases) may be a potential confounding factor in the analysis. However, recently published work has indicated no statistically significant differences in the verotoxin proteins encoded by SF-O157 or non–SF-O157 strains or in their level of toxicity (9). Other virulence factors may contribute to increased likelihood of HUS (4). Our data suggest that infection with SF-O157 results in less severe colitis than does the more common non–SF-O157 infection. Less severe colitis could result in a lower risk for renal disease because less verotoxin would be translocated into the bloodstream and bound to the kidneys. However, patients infected with SF-O157 had anuria for longer periods and consequently had longer sessions of peritoneal and hemodialysis. Although unknown bacterial or host inflammatory cytokines may contribute to enhanced disease progression, this observation is surprising and requires further investigation. Additional research is needed to learn more about the virulence of SF-O157 strains and establish other host factors that contribute to disease progression.

UK Renal Registry 15th annual report: Chapter 4 demography of the UK paediatric renal replacement therapy population in 2011.

Aims: To describe the demographics of the paediatric RRT population under the age of 16 years in the UK and to analyse changes in demography with time. Methods: Data were collected from all 13 paediatric renal centres within the UK. A series of cross-sectional and longitudinal analyses were performed to describe the demographics of paediatric RRT patients. Results: A total of 856 children and young people under 18 with ERF were receiving treatment at paediatric nephrology centres in 2011. At the census date, 80.1% had a functioning transplant, 10.5% were receiving peritoneal dialysis (PD) and 9.4% were receiving haemodialysis (HD). In patients aged <16 years the prevalence of ERF was 56.8 pmarp and the incidence 8.3 pmarp. Analysis of trends over the last 15 years shows that both incidence and prevalence are increasing. A third of the prevalent patients had one or more reported comorbidities. At transfer to adult services, 86% of patients had a functioning renal transplant. Pre-emptive transplantation was seen to occur in 31% of children starting RRT under 16 years, with lower rates seen in girls and ethnic minorities. Survival in childhood amongst children starting RRT was the lowest in those aged less than 2 years. Conclusions: The data provided in this report show increasing trends over 15 years in the incidence and prevalence of established renal failure. This is important for the planning of the provision of care for children needing renal replacement therapy. Further research is required to understand the gender and ethnic differences in pre-emptive transplantation rates and the reduced survival amongst children aged less than 2 years.

UK Renal Registry 14th Annual Report

Aims: To describe the demographics of the paediatric RRT population under the age of 16 years in the UK and to analyse changes in demography with time. Methods: Data were collected from all 13 paediatric renal centres within the UK. A series of cross-sectional and longitudinal analyses were performed to describe the demographics of prevalent paediatric RRT patients. Results: A total of 870 children and young people under 18 with ERF were receiving treatment at paediatric nephrology centres in 2010. At the census date, 76.7% had a functioning transplant, 14.3% were receiving peritoneal dialysis (PD) and 9.0% were receiving haemodialysis (HD). In patients aged <16 years the prevalence of ERF was 59.3 pmarp and the incidence 8.1 pmarp. Analysis of trends over the last 15 years shows that both incidence and prevalence are increasing with the most marked increases in children aged 12–16 years and in ethnic minority groups. A third of the patients have one or more reported comorbidities. At transfer to adult services, 84.9% of patients had a functioning renal transplant. Conclusions: The data provided in this report show increasing trends over 15 years in the incidence and prevalence of established renal failure. This is important for the planning of the provision of care for children needing renal replacement therapy. The inclusion this year of an analysis of the patients transferring to adult services may assist in developing care pathways for this vulnerable group.

Corticosteroid-Free Kidney Transplantation Improves Growth: 2-Year Follow-up of the TWIST Randomized Controlled Trial.

Background Corticosteroid withdrawal (CW) after pediatric kidney transplantation potentially improves growth while avoiding metabolic and other adverse events. We have recently reported the results of a 196 subject randomized controlled trial comparing early CW (tacrolimus, mycophenolate mofetil (MMF), daclizumab, and corticosteroids until day 4) with tacrolimus, MMF, and corticosteroid continuation (CC). At 6 months, CW subjects showed better growth with no adverse impact on acute rejection or graft survival (Am J Transplant 2010; 10: 828–836). This 2-year investigator-driven follow-up study aimed to determine whether improved growth persisted in the longer term. Methods Data regarding growth, graft outcomes and adverse events were collected at 1 year (113 patients) and 2 years (106 patients) after transplantation. The primary endpoint, longitudinal growth calculated as delta height standard deviation score, was analyzed using a mixed model repeated measures model. Results Corticosteroid withdrawal subjects grew better at 1 year (difference in adjusted mean change, 0.25; 95% confidence interval, 0.10, 0.40; P = 0.001). At 2 years, growth remained numerically better in CW subjects (0.20 (−0.01, 0.41); P = 0.06), and significantly better in prepubertal subjects (0.50 (0.16, 0.84); P = 0.004). Bacterial and viral infection was significantly more common in CW subjects at 1 year only. Corticosteroid withdrawal and CC subjects received similar exposure to both tacrolimus and MMF at 1 and 2 years. No significant difference in patient or graft survival, rejection, estimated glomerular filtration rate, or other adverse events was detected. Conclusion Early CW effectively and safely improves growth up to 2 years after transplantation, particularly in prepubertal children.

Use of rapamycin in a transplant patient who developed cyclosporin neurotoxicity

Abstract. We describe the case of a paediatric kidney transplant patient who developed cyclosporin neurotoxicity on day 7 post-transplant. Consequently, her cyclosporin was stopped and she was commenced on rapamycin. Over the next 3 weeks her creatinine remained elevated and she had several episodes of biopsy proven rejection, despite increasing the initial dose of rapamycin by tenfold. Her whole blood rapamycin levels also remained well below the target range of 10–20 ng/ml. On day 38 post-transplant, the decision was made to add tacrolimus to her immunosuppression. At the same time, phenytoin, which had been commenced during her episode of cyclosporin neurotoxicity, was withdrawn. After this point her rapamycin blood levels rapidly increased to within the therapeutic range and she improved clinically. We propose that phenytoin, as a p450 cytochrome enzyme inducer, increased the metabolism of rapamycin in this patient and hence decreased the initial therapeutic effectiveness of this drug.

UK Renal Registry 18th Annual Report: Chapter 10 Clinical, Haematological and Biochemical Parameters in Patients Receiving Renal Replacement Therapy in Paediatric Centres in the UK in 2014: National and Centre-specific Analyses

Introduction: The British Association for Paediatric Nephrology Registry (BAPN) was established to analyse data related to renal replacement therapy (RRT) in children. The registry receives data from the 13 paediatric nephrology centres in the UK. This chapter aims to provide centre specific data so that individual centres can reflect on the contribution that their data makes to the national picture and to determine the extent to which their patient parameters meet nationally agreed audit standards for the management of children with established renal failure (ERF). Methods: Data returns included a mixture of electronic (92%) and paper (8%) returns. Data were analysed to calculate summary statistics and where applicable the percentage achieving an audit standard. The standards used were those set out by the Renal Association and the National Institute for Health and Clinical Excellence. Results: Anthropometric data confirmed that children receiving RRT were short compared to healthy peers. Amongst patients with a height of <2SD between 2001 and 2012, 29.2%were receiving growth hormone if they were on dialysis compared to 11.9% if they had a functioning transplant. Prevalence rates of overweight and obese status in children with ERF remain concerningly high. Blood pressure control remained challenging with wide inter-centre variation although this was significantly better in children with a functioning transplant. Over a quarter of haemodialysis patients and 17.3% of peritoneal dialysis patients were anaemic, compared to only 8.3% of transplanted patients. ESA use in the dialysis population exceeded 90% amongst anaemic patients. The control of renal bone disease remained challenging. Conclusions: Optimising growth and reducing prevalent excess weight in children on RRT remains challenging. The likelihood of complete electronic reporting in the near future with plans for quarterly reporting in the format of the recently finalised NEW paediatric dataset will hopefully improve quality of data and their reporting, allowing improvements in patient care.

UK Renal Registry 17th Annual Report

AIMS To describe the demographics of the paediatric renal replacement therapy (RRT) population under the age of 18 years in the UK and to analyse changes in demography over time. METHODS Data were collected electronically from all 13 paediatric renal centres within the UK. A series of cross-sectional and longitudinal analyses were performed to describe the demographics of paediatric RRT patients. RESULTS A total of 891 children and young people under 18 with established renal failure (ERF) were receiving treatment at paediatric nephrology centres in 2013. At the census date, 80.2% had a functioning transplant, 11.7%were receiving haemodialysis (HD) and 8.1% were receiving peritoneal dialysis (PD). In patients aged ,16 years the prevalence of ERF was 58.2 per million age related population(pmarp) and the incidence 9.3 pmarp. A third of the prevalent patients had one or more reported comorbidities.At transfer to adult services, 85.2% of patients had a functioning renal transplant. Pre-emptive transplantation was seen to occur in a third of children starting RRT under16 years, with lower rates seen in girls and ethnic minorities.Living donation as starting modality has continued to improve with an increase from 8.8% in 1999–2003 to 18.4% in 2009–2013. Survival in childhood amongst children starting RRT was the lowest in those aged less than two years. CONCLUSIONS We report continued improvement in data quality and electronic submission of data returns. The data provided in this report show relatively stable trends of incidence and prevalence in children with established renal failure.

UK Renal Registry 18th Annual Report 2015

The UK Renal Registry (UKRR) continues to provide a national source of NHS healthcare data on patients dependent on renal replacement therapy (RRT) across the four nations. Using electronic reporting and substantial integration across the 71 adult and 13 paediatric renal centres independent audit and analysis of dialysis and transplant activity and care across the UK is provided. The UKRR is part of the UK Renal Association and is funded directly by participating renal centres through an annual capitation fee per patient per annum, currently £19 or 0.01% of annual RRT running costs. The UKRR remains relatively unique amongst renal registries in publishing both centre-specific analyses of indicators of quality of care, such as haemoglobin and also ageadjusted survival statistics for each renal centre [1].