Serum cyclosporine level and orange juice in pediatric renal-transplanted patients

Abstract:  Organ transplant survival has been improved with CsA, but the PK of CsA may be affected by many drugs and foods. This study was performed to investigate the impact of orange juice on PK of CsA in children who had received a renal transplant. This cross-over placebo-controlled study was performed on 10 pediatric kidney-transplanted patients. All children received orange juice (Thomson novel) or water. After morning dose of CsA, patients were given 250 mL orange juice or water and investigation of the PK was performed in 12 h. Co-administration of orange juice with CsA compared with water did not significantly increase the area under the curve from 0–12 h (AUC_0–12) of CsA (orange juice 2833 ± 553, water 3053 ± 1532, p > 0.05). Also, there were not significant effects on peak concentration ( C _max) or time to C _max ( t _max). Orange juice can be used with CsA and there was no interaction between the juice and CsA in pediatric renal transplants.     

Sirolimus pharmacokinetics in pediatric renal transplant recipients receiving calcineurin inhibitor co-therapy

We have previously reported sirolimus (SRL) pharmacokinetics (PK) in pediatric renal transplant recipients on a calcineurin inhibitor (CNI)-free protocol. We now report pediatric SRL PK in pediatric renal transplant patients receiving SRL + CNI. SRL was dosed to achieve target trough levels between 10 and 20 ng/mL. We performed 49 SRL PK profiles in pediatric renal transplant recipients receiving SRL in combination with either cyclosporine (CsA; 25 profiles), or tacrolimus (TCL; 24 profiles). Ten of the SRL + TCL profiles were obtained from children receiving SRL on a b.i.d. dosing regimen. All other SRL profiles were q.d. regimens. We calculated, the maximum concentration (C(max)), AUC, apparent clearance (aCL; dose/AUC) for dose in mg/m(2), and mean residence time (MRT). SRL levels were measured at 6 and 7 time points for b.i.d. and q.d. dosing, respectively. Regression analysis of SRL trough values vs. AUC showed good correlation in the SRL q.d. + CsA, SRL q.d. + TCL, and SRL b.i.d. + TCL groups (r(2) = 0.95, 0.68, and 0.44, respectively). SRL aCL corrected for body surface area was higher in children aged 0-5 yr receiving SRL with either CsA or TCL. SRL dosing schedule should be tailored to each patient. Higher SRL aCL may be present in younger children when administered with CNI.     

Single-dose pharmacokinetics and tolerability of everolimus in stable pediatric renal transplant patients

Everolimus (Certican; RAD), a novel macrolide with potent immunosuppressive and anti-proliferative activities, prevents acute rejection in adult recipients of renal transplantation. This phase I trial conducted in stable pediatric renal transplant patients examined the single-dose pharmacokinetics, safety, and tolerability of everolimus in combination with cyclosporin A (CsA; Neoral) and corticosteroids, with or without azathioprine. Nineteen pediatric patients were enrolled and received a single 1.2 mg/m2 dose of everolimus. Everolimus was safe and well tolerated, with a low incidence of adverse events reported and none judged to be related to the study medication. Everolimus administration did not increase infection rates or produce clinically significant changes in vital signs or changes in electrocardiograms. Apparent clearance and volume of distribution of everolimus increased with age, weight, and body surface area in a generally linear manner across the pediatric demographic ranges. Compared with adults from a previous study, apparent clearance (L/h) and distribution volume (L) were lower in pediatric patients, whereas the elimination half-life was similar. Single-dose everolimus co-administration did not affect the steady-state pharmacokinetics of CsA. Based on this information, pediatric patients will need a dose scaled down for body size, but can probably maintain the same twice-daily dosing schedule used in adults.     

What is the role for mycophenolate mofetil in pediatric renal transplantation?

Mycophenolate mofetil (MMF) has gained considerable popularity in pediatric renal transplantation. This popularity is largely a result of data from three large trials of MMF in adult cadaveric transplant patients who demonstrated a decreased rate of acute rejection episodes when treated with cyclosporin A (CsA), prednisone, and MMF compared with those receiving CsA, prednisone, and azathioprine (AZA) or placebo. However, the ability of MMF to reduce acute rejection appears to be limited to the first month post-transplant, and its effectiveness with microemulsion CsA or tacrolimus-based regimens has not been proven. In addition, there are currently no data that convincingly demonstrate that this agent improves graft survival, patient survival, graft function or protects against chronic rejection. Finally, there may be an increased risk for severe cytomegalovirus (CMV) disease and lymphoproliferative disorder with central nervous system involvement in patients treated with MMF. These data call into question the role of MMF in current immunosuppressive regimens.     

Longitudinal evaluation of the pharmacokinetics of cyclosporin microemulsion (Neoral) in pediatric renal transplant recipients and assessment of C2 level as a marker for absorption

BACKGROUND: There are important differences in CsA pharmacokinetics between adult and pediatric patients, such that pharmacokinetic data can not necessarily be extrapolated from the adult to the pediatric setting. Research in adult renal transplant patients has shown that adequate cyclosporin exposure (AUC0-4) in the first week post-transplant is important for successful clinical outcome, and that cyclosporin concentration at 2 h post-dose (C2) provides the optimal single-time point marker for AUC0-4. Clinically, dose management based on C2 level results in a low incidence of acute rejection in the adult renal transplant population. The study reported here undertook pharmacokinetic profiling in de novo renal transplant patients over a period of 6 months and retrospectively assessed alternative monitoring strategies based on pharmacokinetic findings and clinical outcomes. METHODS: This open-label, observational, prospective study was carried out at four UK transplant centers over a period of 6 months in pediatric de novo renal transplant recipients receiving the microemulsion formulation of cyclosporin (Neoral) according to local protocol. Twelve-hour pharmacokinetic profiles (8-16 blood samples each) were performed on days 5 and 14 and at weeks 4, 13 and 26 post-transplant. RESULTS: Thirty-two patients were recruited (median age 10 yr, range 3-18 yr). At 6 months, patient survival was 100% and graft survival was 91%. The incidence of clinically determined acute rejection was 41% (13 of 32). Six patients discontinued Neoral before 6 months: three due to graft loss, one due to rejection, one due to renal toxicity and one due to hypertrichosis. At all time points studied, C2 correlated more closely with AUC0-4 and with AUC0-12 than did the pre-dose cyclosporin concentration (C0, or trough). Patients achieving C2 > 1.5 microg/mL by the fifth postoperative day experienced no acute rejection in the first 6 months, compared with a 50% rejection rate among patients with C2 < 1.5 microg/mL (P < 0.05). Binary logistic regression analysis showed that C2 level >1.7 microg/mL was associated with approximately 90% probability of freedom from acute rejection. Analysis of renal function across patients grouped according to cyclosporine exposure (AUC0-4, C2) showed no adverse effects of higher/increased exposure on creatinine or GFR. CONCLUSIONS: C2 level provides a more reliable marker for CsA exposure than C0 in pediatric renal transplant recipients, and is more closely predictive of acute rejection risk. A C2 target of 1.7 microg/mL appears appropriate in this population during the immediate post-transplant period in order to maximize clinical benefit.     

Pharmacokinetics of enteric-coated mycophenolate sodium in stable pediatric renal transplant recipients

This study aims to characterize the pharmacokinetics of mycophenolic acid (MPA) and its glucuronide metabolite (mycophenolic acid 7-O-glucuronide, MPAG) following single oral administration of enteric-coated mycophenolate sodium (EC-MPS, myfortic) at an approximate dose level of 450 mg/m(2) body surface area (BSA) to 25 stable renal transplant recipients (aged 5-16 yr), and to evaluate the safety and tolerability of EC-MPS in this pediatric population. Patients had been maintained on a cyclosporine emulsion, Neoral-based immunosuppressive regimen for at least 3 months and had received their first or second renal transplant more than 6 months prior to entry into the study. After a brief lag phase (t(lag) 0.75 h), MPA was rapidly absorbed (t(max) 2.5 h) and rapidly converted to MPAG (t(max) 3.25 h), with relatively high plasma concentrations of MPAG (C(max) 67.7 microg/mL) compared with MPA (C(max) 36.3 microg/mL). The elimination half-life for MPAG was slightly longer than for MPA (approximately 13 h vs. 8.5 h), and the apparent oral clearance of MPA was approximately 0.2 L/h/kg. The pharmacokinetics of MPA or MPAG were not affected by age, body weight or BSA, within the study population. The pharmacokinetic results for pediatric patients are comparable with those obtained previously in adults, although exposure based on AUC(0-infinity) was approximately 23% higher, and this finding may be a result of dosing on the basis of BSA, rather than body weight. The recommended dose of EC-MPS in pediatric patients is 400-450 mg/m(2) twice daily or, alternatively, approximately 10-14 mg/kg twice daily when used in combination with cyclosporine microemulsion.     

Pharmacodynamic monitoring of cyclosporine A by NFAT‐regulated gene expression and the relationship with infectious complications in pediatric renal transplant recipients

Billing H, Giese T, Sommerer C, Zeier M, Feneberg R, Meuer S, Tönshoff B. Pharmacodynamic monitoring of cyclosporine A by NFAT‐regulated gene expression and the relationship with infectious complications in pediatric renal transplant recipients.
Pediatr Transplantation 2010: 14:844–851. © 2010 John Wiley & Sons A/S. Abstract: Pharmacokinetic monitoring of CsA is unsatisfactory, because at comparable CsA blood concentrations, the frequency and severity of adverse effects vary considerably among patients. We have therefore recently developed a precise, reliable, and robust whole‐blood pharmacodynamic assay that measures the suppression of CsA‐target genes in T lymphocytes. Because of the different characteristics of CsA pharmacokinetics in children and the higher propensity for infectious complications, this assay requires validation in the pediatric patient population. We therefore quantified in a prospective study of 45 pediatric renal transplant recipients the residual expression of NFAT‐regulated genes in lymphocytes by RT‐PCR and correlated these findings with the frequency of recurrent infections in the maintenance period post‐transplant. Patients with recurrent infections showed a significantly stronger inhibition of NFAT‐regulated gene expression (18.2%) than patients without recurrent infections (31.7%; p = 0.012). This difference was specific, because various PK parameters of CsA and the concomitant immunosuppressive therapy were comparable between patients. Multivariate regression analysis showed that patient age and residual NFAT‐regulated gene expression were the only independent determinants of recurrent infections. By ROC curve analysis, a cutoff value of 23% residual NFAT‐regulated gene expression had the highest sensitivity (71.1%) and specificity (65.4%) for the discrimination of patients with and without recurrent infections. Pharmacodynamic monitoring of CsA by measurement of residual NFAT‐regulated gene expression in T lymphocytes has the potential to identify over‐immunosuppressed pediatric renal transplant recipients and is therefore a useful tool for the optimization of CsA therapy.     

Predictive value of pretransplantation cyclosporine pharmacokinetic studies on initial post-transplantation dosing in pediatric kidney allograft recipients

Despite the introduction of a variety of new immunosuppressive agents, cyclosporine A (CsA) has maintained a strong position in pediatric transplantation (Tx). Post-Tx dosing with CsA is a challenging task because of the narrow therapeutic window of the drug, the great individual variability of metabolism and the lack of consensus about the optimal dosage and targeted blood concentration. Sufficient administration of CsA may be protective against acute rejections and other early complications after Tx, which is crucial for the long-term survival of the graft. Individual doses based on pre-Tx pharmacokinetic studies might be helpful in achieving optimal early concentrations of CsA. To asses the usefulness of pharmacokinetic studies, we retrospectively compared the post-Tx doses administered with the individually predicted doses between 1988 and 1998. Multiple regression of data on 65 de novo renal transplant recipients, 1.1-15.5 yr old, was used to analyze the significance of the predicted dose, trough blood concentration of CsA (B-CsA), serum creatinine and age at the time of Tx in explaining the doses used during the first three post-Tx weeks. Patients were grouped according to age (<2, 2-8 and >8 yr), according to the predicted dose (within or outside +/-25% of age-group average), and according to the oral formulation of CsA. Standard dosing scheme was simulated by using age-specific average doses in the place of the individual predicted doses. Administered doses of CsA were high [averaging 22.6 (504), 20.7 (484), and 12.4 mg/kg/d (329 mg/m2/d) for patients <2, 2-8, and >8 yr old] but the average B-CsA remained in the target range of 250-450 microg/L. The predicted dose and age were significant parameters in explaining the administered doses during the first 3 wk after Tx. B-CsA and S-creatinine were non-significant. The predicted doses were used to initiate the dosing of CsA after Tx (R2 = 0.70) and adjustments to dosing were made during the next weeks (R2 = 0.59, 0.52). Multiple regression model showed better fit for 60% of our patients, who had atypical predicted doses (R2 = 0.74, 0.60, 0.64 for first, second and third post-Tx weeks, respectively), most remarkably in patients <2 yr of age, than for the study population as a whole. A simulated standard dose was not able to explain the administered doses of CsA. In conclusion, pre-Tx pharmacokinetic studies are valuable for determining individual post-Tx starting doses, especially for those patients who need high or low doses of CsA. Individual dosing led to relatively high initial CsA doses, which could be significant for the long-term survival of the graft.     

Sodium ferric gluconate for post-transplant anemia in pediatric and young adult renal transplant recipients

Post-transplant anemia is a widespread problem among pediatric renal transplant recipients. Many clinicians treat post-transplant anemia in a manner similar to treatment of anemia in dialysis patients, including the use of intravenous iron, such as sodium ferric gluconate (SFG). Data on pediatric dosing of SFG are limited to rare small series containing few or no renal transplant recipients. We conducted a retrospective chart review of practice patterns at our institution to evaluate doses used, hemoglobin response and adverse events. We identified 15 renal transplant recipients who received SFG during the 28-month study period. Data from 14 of these patients were available for analysis. Patients received between one and six doses of SFG to yield a total dose of 100-1000 mg or 2.7-23.7 mg/kg. The largest doses given during a single infusion ranged from 1.9 to 6.4 mg/kg. The mean hemoglobin level increased from 101 +/- 16 to 114 +/- 21 g/L (p = 0.0092) following SFG therapy. Adverse events were recorded for three patients. Treatment with SFG appears to yield some improvement in anemia in renal transplant recipients, but the paucity of published information on this topic highlights the need for stronger data, particularly with respect to pediatric patients.     

Acquired renal cysts after pediatric liver transplantation: association with cyclosporine and renal dysfunction

Abstract:  ACKD has been observed in children on dialysis and with chronic renal insufficiency. In one report, ACKD was observed in 30% of pediatric liver transplant recipients after 10 yr. We retrospectively reviewed all renal imaging and measurements of GFR of 235 childhood liver transplant recipients with no known risk for renal cyst formation, no evidence of renal cyst(s) at the time of transplantation and renal imaging at least one yr post-transplant. Twenty-six patients (11%) developed one or more cyst(s). Mean GFR was significantly lower in patients with renal cyst(s). Two (1.4%) of the 146 patients treated with tacrolimus and 24 (27%) of the 89 patients treated with CsA acquired renal cyst(s) (p < 0.001). CsA-treated patients had significantly lower GFR. Multivariate analysis identified CsA as the only independent variable associated with ACKD. These results confirm that ACKD can be a late complication of pediatric liver transplantation. Those at most risk are at least 10-yr post-liver transplantation, have been treated with CsA and have impaired renal function. We speculate that ACKD in these patients is the result of calcineurin inhibitor nephrotoxicity. Whether patients with ACKD will be prone to develop solid renal tumors is unknown.     

Tacrolimus: the good, the bad, and the ugly

The aim of this study was to evaluate the efficacy and side-effects of tacrolimus in pediatric transplant patients previously receiving cyclosporin A (CsA). This study was a retrospective chart review strengthened by a concomitant patient interview. Eleven pediatric cardiac or renal transplant patients, who had been converted from CsA to tacrolimus from October 1995 to January 1999 at The Cleveland Clinic Foundation, were included; there were six renal and five cardiac transplant patients. Each chart was reviewed to assess transplanted organ function pre- and post-conversion. For the six renal transplant patients, creatinine levels and biopsy findings were evaluated. For the five cardiac transplant patients, cardiac catheterization and routine biopsy data were analyzed likewise. Epstein Barr virus (EBV) status was also evaluated in each patient. In addition, each parent or patient was interviewed to ascertain dates of transplant, current medications, and side-effects. The patients' ages ranged from 6 to 20 yr (mean age 14.6 yr). All patients had been converted to tacrolimus. Eight patients were converted for treatment of refractory rejection, two were converted because of CsA-associated side-effects, and one patient was converted empirically for a history of multiple previous transplant rejections. Seven out of eight patients who received tacrolimus for rejection therapy improved. One patient had complete resolution of gingival hyperplasia. Another patient who previously developed hemolytic uremic syndrome on CsA had no further evidence of hemolysis. Four patients were weaned off steroid therapy. Despite conversion, two renal transplant patients progressed to chronic rejection. Five patients exhibited no side-effects. Side-effects experienced included transient hyperglycemia in conjunction with steroid use, headaches, and tremors that subsided rapidly. Four of 11 patients developed post-transplant lymphoproliferative disease (PTLD). Fortunately, reducing the dose of tacrolimus and/or surgical resection of the mass (if present), eradicated the disease. In conclusion, conversion therapy successfully provides an alternate treatment for acute rejection. It also enabled some patients to discontinue steroid therapy, maximizing growth potential. PTLD is a severe, potentially life-threatening complication that needs to be recognized and monitored closely. In conclusion, tacrolimus has been shown to be a very effective agent for the treatment of refractory organ rejection, but must be used cautiously.     

Immune cell function assay does not identify biopsy‐proven pediatric renal allograft rejection or infection

Management of pediatric renal transplant patients involves multifactorial monitoring modalities to ensure allograft survival and prevent opportunistic infection secondary to immunosuppression. An ICFA, which utilizes CD4 T‐cell production of ATP to assess immune system status, has been used to monitor transplant recipients and predict susceptibility of patients to rejection or infection. However, the validity of this assay to reflect immune status remains unanswered. In a two‐yr retrospective study that included 31 pediatric renal transplant recipients, 42 patient blood samples were analyzed for immune cell function levels, creatinine, WBC (white blood cell) count, immunosuppressive drug levels, and viremia, concurrent with renal biopsy. T‐cell ATP production as assessed by ICFA levels did not correlate with allograft rejection or with the presence or absence of viremia. ICFA levels did not correlate with serum creatinine or immunosuppressive drug levels, but did correlate with WBC count. The ICFA is unreliable in its ability to reflect immune system status in pediatric renal transplantation. Further investigation is necessary to develop methods that will accurately predict susceptibility of pediatric renal transplant recipients to allograft rejection and infection.     

De novo therapy with everolimus and reduced‐exposure cyclosporine following pediatric kidney transplantation: A prospective,multicenter, 12‐month study

Prospective data regarding the de novo use of everolimus following kidney transplantation in children are sparse. In a prospective, 12‐month, single‐arm, open‐label study, pediatric kidney transplant patients received everolimus (target trough concentration ≥3 ng/mL) with reduced‐exposure CsA and corticosteroids, with or without basiliximab induction. Sixteen of the 18 patients completed the study on‐treatment. Age range was 2–16 yr (mean 10.9 yr); eight patients received a living donor graft. Mean (s.d.) everolimus level was 7.4 (3.1) ng/mL during the first 12 months post‐transplant. There were no cases of BPAR, graft loss, or death during the study. Protocol biopsies were performed at month 12 in seven patients, with subclinical (untreated) acute rejection diagnosed in one case. Mean (s.d.) estimated GFR (Schwartz formula) was 98 (34) mL/min/1.73 m² at month 12. Three patients experienced one or more serious adverse events with a suspected relation to study medication. One patient discontinued study medication due to post‐transplant lymphoproliferative disease (5.6%). Everolimus with reduced‐dose CsA and corticosteroids achieved good efficacy and renal function and was well tolerated in this small cohort of pediatric kidney transplant patients. Controlled trials are required to answer remaining questions about the optimal use of everolimus in this setting.     

Reversal of tacrolimus-related hypertrophic obstructive cardiomyopathy 5 years after kidney transplant in a 6-year-old recipient

Hypertrophic obstructive cardiomyopathy (HOCM) is an unusual but serious side-effect of tacrolimus (TAC) based immunosuppression primarily affecting pediatric patients after solid organ transplant. TAC-induced HOCM has already been described in patients after liver, bowel and heart transplant shortly after the procedure. Herein, we present the first case report of TAC-induced HOCM in a young renal transplant recipient 5 yr after renal transplant. The condition was diagnosed by ECHO and EKG and successfully treated by discontinuation of TAC followed by conversion to cyclosporine (CsA).     

Indications, results, and complications of tacrolimus conversion in pediatric renal transplantation

It is the practice of many pediatric renal transplant programs to 'convert' children taking cyclosporin A (CsA) to tacrolimus, although the indications for, outcome, and complications of this practice remain obscure. To better understand these aspects of tacrolimus 'conversion', a fax survey was sent to 119 North American pediatric renal transplant centers. Analyzable responses were received from 52 centers (44%), and included data from approximately 1,815 pediatric renal transplants performed between 1991 and 98. Strong indications for tacrolimus conversion were: antibody-resistant rejection, CsA-resistant rejection, and CsA intolerance (strong indication in 72%, 65%, and 52% of centers, respectively). Steroid-resistant rejection and cosmetic side-effects were considered strong indications less often. Initial anti-rejection therapy was usually increased corticosteroid dose (47/52 centers). Antibody therapy was most commonly used for steroid-resistant rejection (44 centers). For steroid- and antibody-resistant rejection, tacrolimus conversion was most common (33 centers). Tacrolimus conversion for antibody-resistant rejection led to improvement of serum creatinine (SCr) in 27% of patients, stabilization of SCr in 46%, worsening of SCr in 11%, and graft loss in 16%. Reported complications after tacrolimus conversion included hyperglycemia, hyperkalemia, lymphoproliferative disorder, infection, and neurologic problems. We conclude that the major indication for tacrolimus conversion in pediatric transplant programs appears to be rejection. Outcome after tacrolimus conversion appears good, with the majority of patients experiencing stable or improved allograft function. These data provide direction for further study, including timing of tacrolimus conversion and interaction with other therapies.     

Dyslipidemia after pediatric renal transplantation—The impact of immunosuppressive regimens

Dyslipidemia contributes to cardiovascular morbidity and mortality in pediatric transplant recipients. Data on prevalence and risk factors in pediatric cohorts are, however, scarce. We therefore determined the prevalence of dyslipidemia in 386 pediatric renal transplant recipients enrolled in the CERTAIN registry. Data were obtained before and during the first year after RTx to analyze possible non‐modifiable and modifiable risk factors. The prevalence of dyslipidemia was 95% before engraftment and 88% at 1 year post‐transplant. Low estimated glomerular filtration rate at 1 year post‐transplant was associated with elevated serum triglyceride levels. The use of TAC and of MPA was associated with significantly lower concentrations of all lipid parameters compared to regimens containing CsA and mTORi. Immunosuppressive regimens consisting of CsA, MPA, and steroids as well as of CsA, mTORi, and steroids were associated with a three‐ and 25‐fold (P<.001) increased risk of having more than one pathologic lipid parameter as compared to the use of TAC, MPA, and steroids. Thus, amelioration of the cardiovascular risk profile after pediatric RTx may be attained by adaption of the immunosuppressive regimen according to the individual risk profile.     

The potential role of rapamycin in pediatric transplantation as observed from adult studies

Although pediatric patient and renal graft survival rates have shown marked improvements during the past decade, the persistent toxicities of immunosuppressive drugs and chronic allograft attrition remain major obstacles in transplant therapy. Results in adult patients suggest that complete steroid withdrawal is possible in the majority of recipients under treatment with a cyclosporin A-rapamycin (CsA RAPA) regimen. Furthermore, preliminary studies suggest that a marked reduction in the dose of CsA may be possible under the umbrella of RAPA coverage. The gain in immunosuppressive efficacy afforded by RAPA has not only been obtained without an increased morbidity owing to infectious or neoplastic causes, but also with the potential for reducing the incidence and/or progression of chronic rejection.     

Risk factors for bone mineral density loss in pediatric renal transplant patients

Bone mineral density (BMD) is decreased in both adult and pediatric renal transplant recipients. To investigate the risk factors associated with this decrease in BMD post-renal transplant, we studied 33 children, aged 7-22 yr, who had received a renal transplant from 0.3 to 10 yr prior to this study. BMD analysis of the total body, spine, and femur was carried out by using dual-energy X-ray absorptiometry (DEXA). Age, weight, Tanner stage, time on dialysis prior to transplantation, cumulative corticosteroid dosage, and cyclosporin A (CsA) dosage since transplantation, and use of corticosteroid therapy prior to transplantation, were recorded. Spine, femur, and total body BMD Z-scores were greater than two standard deviations (2 SD) below the mean in 45%, 42%, and 17% of patients, respectively. Age correlated inversely with total body and spine BMD Z-scores (p = 0.001 and p = 0.008); no child under 14 yr of age had a total body or spine BMD Z-score greater than 2 SD below the mean for age. Patients at a Tanner stage of 4 or 5 had lower total body and spine BMD Z-scores than did patients at Tanner stages 1-3 (p = 0.043). Time post-transplant correlated inversely with both spine and total body BMD Z-score (p = 0.013 and p = 0.023). Only total body BMD Z-score correlated inversely with cumulative corticosteroid dose (in g, p = 0.045). BMD did not correlate with cumulative CsA dose. Black patients tended to have decreased total body BMD compared with Caucasian patients. In pediatric renal transplant patients, decreases in BMD start in adolescence. Risk factors for BMD loss in these patients include increasing age, time post-transplant, increasing Tanner stage, and ethnicity. Longitudinal studies in these patients and strategies to improve BMD are needed.     

Effect of age, ethnicity, and glucocorticoid use on tacrolimus pharmacokinetics in pediatric renal transplant patients

Tacrolimus has become an effective alternative to cyclosporine as a component of primary immunosuppression in pediatric renal transplant patients, but the information on the pharmacokinetic characteristics of tacrolimus in young patients is still limited. The primary objective of this study was to determine the effect of patient age, ethnicity, and concurrent steroid administration on tacrolimus pharmacokinetics in pediatric renal transplant patients. The study population consisted of 30 pediatric patients, age 1.5-18.6 yr, who received a kidney transplant between July 1999 and February 2004. After twice daily dosing was stabilized based on clinical judgment, at least 5 days postoperatively, tacrolimus levels were drawn prior to, and 1, 2, 4, 8, and 12 h after the morning dose. The mean dose of tacrolimus was 0.12 mg/kg/dose. Mean trough level was 11.9 +/- 5.0 ng/mL. Mean area under the curve (AUC) was 192 +/- 84 with a range of 78-360 h x (ng/mL). The correlation between trough level and AUC was only fair (r = 0.74); later time points correlated better with AUC, and an excellent correlation (r = 0.96) was obtained between the mean of trough and 2-h level (C(2)) and AUC. There was a negative correlation between age and dose per body weight (r = -0.68). African-American patients had marginally lower drug exposure with similar dosing. Three age groups (<5, 5-12, and >12 yr) were compared with respect to dosing and AUC. Despite similar AUC in all three groups, the mean dose per kg required to achieve the AUC was 2.7- and 1.9-fold higher in the <5 and 5-12-yr groups, respectively, compared with the >12-yr group. Nine of the 30 patients were on a totally steroid-free regimen. Their tacrolimus dose and trough levels were similar to those of steroid-exposed patients, but their mean AUC was 41% higher. Our results show an inverse correlation between age and required tacrolimus dose, wide interindividual variation, and greater exposure with steroid-free regimen despite no change in trough level.     

Benefits of conversion from mycophenolate mofetil to enteric-coated mycophenolate sodium in pediatric renal transplant patients with stable graft function

Abstract:  Conversion from MMF to EC-MPS may reduce GI complications and permit increased MPA dosing with a concomitant reduction in CNI dose. In a prospective trial, paediatric renal transplant patients with stable graft function were converted from MMF to EC-MPS and followed-up for 12 months. Data from 28 patients (mean age 13.9 ± 3.1 yr) were available for analysis. Mean EC-MPS dose increased significantly from conversion to month 12 (668 ± 81 mg/m²/day vs. 747 ± 98 mg/m²/day, p < 0.001). CsA-ME dose (n = 23) decreased from 5.3 ± 1.7 mg/kg/day at conversion to 4.6 ± 1.4 mg/kg/day at month 12 (p = 0.010). cGFR increased from 69.5 ± 23.3 mL/min/1.73 m² at the time of conversion to 80.7 ± 30.7 mL/min/1.73 m² at month 12 (p = 0.007). The number of patients reporting at least one GI event during six months prior to conversion was 15/28 (53.6%), declining to 8/28 (28.6%) at month 6 post-conversion and 5/28 (17.8%) at month 12. This single-arm study suggests that conversion of paediatric renal transplant patients from MMF to EC-MPS does not compromise efficacy and leads to improved GI tolerability. MPA dose increased and CsA-ME dose decreased significantly, with an associated improvement in calculated GFR. A large-scale controlled trial is required to confirm these promising findings.