Sara Bremer

Declining intracellular T-lymphocyte concentration of cyclosporine a precedes acute rejection in kidney transplant recipients.

Background. We investigated cyclosporine A (CsA) concentrations at the site of action, inside T-lymphocytes, to evaluate its applicability as a new supplementary therapeutic drug monitoring method after renal transplantation. Method. In this prospective single-center study, 20 kidney transplant recipients, mean age 54 (range 21–74) years, on CsA-based immunosuppression were included within 2 weeks posttransplant and followed for 3 months. Nine patients also had one full 12-hour pharmacokinetic profile performed. T-lymphocytes were isolated from 7 ml whole blood using Prepacyte and intracellular CsA concentrations were determined using a validated liquid chromatography double mass spectrometry method. Results. Seven patients (35%) experienced acute rejections (all biopsy verified) during the first three months posttransplantation. Intracellular CsA concentrations tended to decline 1 week prior to acute rejection and the decrease was significant (−27.1±14.6%, P=0.014) three days before the rejection episodes were recognized clinically. In addition, the intracellular CsA area under the curve 0–12 measured during stable phase was 182% higher in the rejection-free patients (P=0.004). There was no difference between patients experiencing rejection and the rejection-free patients with respect to CsA C2-levels, dose (mg/kg), human leukocyte antigen mismatch, donor age, recipient age, or ABCB1 genotyping. Conclusion. Intracellular CsA T-lymphocyte concentrations declined significantly 3 days prior to a rejection episode and there was a general lower intracellular exposure of CsA in recipients experiencing rejection. Intracellular measurement of CsA therefore seems to have a potential to further improve individualization of therapeutic drug monitoring. Larger studies are needed to elucidate the role for intracellular T-lymphocyte measurements in ordinary clinical care, for both CsA and other immunosuppressive drugs.

Impact of OATP1B1, MDR1, and CYP3A4 Expression in Liver and Intestine on Interpatient Pharmacokinetic Variability of Atorvastatin in Obese Subjects

Individual variability in expression and function of organic anion‐transporting polypeptide 1B1 (OATP1B1), multidrug resistance protein 1 (MDR1), and/or cytochrome P450 3A4 (CYP3A4) may impact the clinical response of many drugs. We investigated the correlation between expression of these proteins and pharmacokinetics of atorvastatin, a substrate of all three, in 21 obese patients with paired biopsies from liver and intestinal segments. The patients were also screened for the SLCO1B1 c.521T→C variant alleles. Approximately 30% (r2 = 0.28) of the variation in oral clearance (CL/F) of atorvastatin was explained by hepatic OATP1B1 protein expression (P = 0.041). Patients carrying the SLCO1B1 c.521C variant allele (homozygous, n = 4; heterozygous, n = 2) exhibited 45% lower CL/F of atorvastatin than the c.521TT carriers (P = 0.067). No association between hepatic and intestinal expression of MDR1 or CYP3A4 and atorvastatin pharmacokinetics was found (P > 0.149). In conclusion, this study suggests that OATP1B1 phenotype is more important than CYP3A4 and MDR1 phenotypes for the individual pharmacokinetic variability of atorvastatin.

Reduced elimination of cyclosporine A in elderly (>65 years) kidney transplant recipients.

Background. Physiologic functions that may affect pharmacokinetics of drugs are altered in elderly patients. The current study was performed to elucidate the effect of age on cyclosporine A (CsA) pharmacokinetics in renal transplant recipients. Method. Twenty-five renal transplant recipients on CsA treatment were included in the study. CsA doses were adjusted by C2 monitoring. The patients were divided into two groups based on age; elderly: more than 65 years (n=11, mean 73 years) and younger: 18 to 64 years (n=14, mean 43 years). A full 12-hr pharmacokinetic profile was performed during stable phase. CsA whole blood and intracellular T-lymphocytes concentrations (first 6 hr) were measured. Genotyping of the CYP3A5*1/*3 and ABCB1 (C1236T, G2677T, C3435T) polymorphisms and quantification of whole blood mRNA ABCB1 expression were performed in all patients. Results. Elderly patients achieved target C2 levels with lower CsA doses than the younger patients (4.3±0.8 vs. 6.1±2.1 mg/day/kg, P=0.025) because of lower clearance of CsA (22.7±5.1 vs. 30.5±11.1 L/hr, P=0.031). Elderly patients also showed 44% higher intracellular-to-whole blood CsA ratio than younger patients (P=0.02). Neither the CYP3A5*1, the ABCB1 genotypes nor mRNA ABCB1 expression revealed any significant influence on CsA pharmacokinetics. Conclusion. The clearance of CsA decreased with increasing age. In addition, elderly patients had a significant larger proportion of the whole blood CsA concentration located at the site of action (within T lymphocytes). This indicates that in elderly recipients it might be safe to aim for an even lower whole blood target levels than current guidelines propose.

Improved tacrolimus target concentration achievement using computerized dosing in renal transplant recipients – a prospective, randomized study

Background Early after renal transplantation, it is often challenging to achieve and maintain tacrolimus concentrations within the target range. Computerized dose individualization using population pharmacokinetic models may be helpful. The objective of this study was to prospectively evaluate the target concentration achievement of tacrolimus using computerized dosing compared with conventional dosing performed by experienced transplant physicians. Methods A single-center, prospective study was conducted. Renal transplant recipients were randomized to receive either computerized or conventional tacrolimus dosing during the first 8 weeks after transplantation. The median proportion of tacrolimus trough concentrations within the target range was compared between the groups. Standard risk (target, 3-7 &mgr;g/L) and high-risk (8-12 &mgr;g/L) recipients were analyzed separately. Results Eighty renal transplant recipients were randomized, and 78 were included in the analysis (computerized dosing (n = 39): 32 standard risk/7 high-risk, conventional dosing (n = 39): 35 standard risk/4 high-risk). A total of 1711 tacrolimus whole blood concentrations were evaluated. The proportion of concentrations per patient within the target range was significantly higher with computerized dosing than with conventional dosing, both in standard risk patients (medians, 90% [95% confidence interval {95% CI}, 84-95%] vs 78% [95% CI, 76-82%], respectively, P < 0.001) and in high-risk patients (medians, 77% [95% CI, 71-80%] vs 59% [95% CI, 40-74%], respectively, P = 0.04). Conclusions Computerized dose individualization improves target concentration achievement of tacrolimus after renal transplantation. The computer software is applicable as a clinical dosing tool to optimize tacrolimus exposure and may potentially improve long-term outcome.

Expression of IMPDH1 and IMPDH2 after transplantation and initiation of immunosuppression.

Background. Mycophenolic acid (MPA) mediates immunosuppressive effects by inhibiting inosine monophosphate dehydrogenase (IMPDH). Induction of IMPDH activity has been observed in whole blood and erythrocyte samples during immunosuppressive therapy. Information concerning the mechanisms for increased IMPDH activity is limited and the potential implications of induction have been debated. Methods. Whole blood, CD4+ cell, and reticulocyte samples were collected from 30 renal transplant patients pre- and posttransplantation. The expressions of two IMPDH isoforms, type 1 and 2, were analyzed by real-time reverse-transcription polymerase chain reaction and quantified using a housekeeping gene index. The IMPDH activity was determined by ultraviolet high-performance liquid chromatography. Results. Transplantation and the initiation of immunosuppressive therapy was associated with increased IMPDH1 (50–88%, P<0.0005) and decreased IMPDH2 (42–56%, P<0.0005) expression. In CD4+ cells, however, IMPDH2 increased (15%, P=0.009). These changes are probably related to glucocorticoid effects. Two weeks posttransplant, MPA-treated patients displayed elevated IMPDH 1 and 2 in reticulocytes, suggesting enzyme induction in these cells during prolonged MPA therapy. Patients with acute rejection during follow-up demonstrated higher IMPDH2 expression in CD4+ cells pretransplant than nonrejecting patients (median expression 1.26 vs. 0.87 respectively, P=0.017). Conclusions. Knowledge of changes in IMPDH 1 and 2 expression after transplantation and initiation of immunosuppression is important considering the action of MPA on IMPDH and the potential for pharmacodynamic monitoring of MPA by measuring IMPDH activity. The expression of IMPDH2 in CD4+ cells pretransplant may be an indicator of immune activation.

Inclusion of CYP3A5 genotyping in a nonparametric population model improves dosing of tacrolimus early after transplantation

Following organ engraftment, initial dosing of tacrolimus is based on recipient weight and adjusted by measured C0 concentrations. The bioavailability and elimination of tacrolimus are affected by the patients CYP3A5 genotype. Prospective data of the clinical advantage of knowing patients CYP3A5 genotype prior to transplantation are lacking. A nonparametric population model was developed for tacrolimus in renal transplant recipients. Data from 99 patients were used for model development and validation. A three‐compartment model with first‐order absorption and lag time from the dosing compartment described the data well. Clearances and volumes of distribution were allometrically scaled to body size. The final model included fat‐free mass, body mass index, hematocrit, time after transplantation, and CYP3A5 genotype as covariates. The bias and imprecision were 0.35 and 1.38, respectively, in the external data set. Patients with functional CYP3A5 had 26% higher clearance and 37% lower bioavailability. Knowledge of CYP3A5 genotype provided an initial advantage, but only until 3‐4 tacrolimus concentrations were known. After this, a model without CYP3A5 genotype predicted just as well. The present models seem applicable for clinical individual dose predictions but need a prospective evaluation.

Use of generic tacrolimus in elderly renal transplant recipients: precaution is needed.

Background Proper bioequivalence studies comparing original with generic immunosuppressive drugs in patients are limited, especially in the increasing population of elderly renal transplant recipients. We performed an open-label, single-center, prospective, randomized, cross-over study and compared steady-state pharmacokinetics (PK) of a generic tacrolimus (Tacni) formulation with the original (Prograf) in renal transplant recipients older than 60 years. Methods Twenty-eight patients, with a median age of 69 years (range, 60 to 78), were randomized at time of transplantation to receive original or generic tacrolimus, and 25 (21 men, 4 women) provided two evaluable 12-hr PK profiles. The PK investigations were performed in a stable phase approximately 6 and 8 weeks postengraftment. After the first PK investigation, tacrolimus formulations were switched (1:1 dose ratio). Results Generic tacrolimus did not meet the bioequivalence criteria; the area under the curve0–12 ratio of generic-original tacrolimus formulation was 1.17 (90% confidence interval, 1.10–1.23) and the Cmax ratio was 1.49 (90% confidence interval, 1.35–1.65). The generic formulation also showed a shorter time to Cmax (Tmax) (P=0.04). Importantly, the lack of bioequivalence was not reflected in the standard monitoring parameter, trough concentrations (P=0.80). Conclusion Generic tacrolimus (Tacni) was not found to be bioequivalent to the original formulation in elderly renal transplant recipients. The significantly higher systemic exposure of tacrolimus, despite similar trough concentrations, may in the long run increase the risk of adverse effects.

Improved prediction of tacrolimus concentrations early after kidney transplantation using theory-based pharmacokinetic modelling

Aims The aim was to develop a theory-based population pharmacokinetic model of tacrolimus in adult kidney transplant recipients and to externally evaluate this model and two previous empirical models. Methods Data were obtained from 242 patients with 3100 tacrolimus whole blood concentrations. External evaluation was performed by examining model predictive performance using Bayesian forecasting. Results Pharmacokinetic disposition parameters were estimated based on tacrolimus plasma concentrations, predicted from whole blood concentrations, haematocrit and literature values for tacrolimus binding to red blood cells. Disposition parameters were allometrically scaled to fat free mass. Tacrolimus whole blood clearance/bioavailability standardized to haematocrit of 45% and fat free mass of 60 kg was estimated to be 16.1 l h−1 [95% CI 12.6, 18.0 l h−1]. Tacrolimus clearance was 30% higher (95% CI 13, 46%) and bioavailability 18% lower (95% CI 2, 29%) in CYP3A5 expressers compared with non-expressers. An Emax model described decreasing tacrolimus bioavailability with increasing prednisolone dose. The theory-based model was superior to the empirical models during external evaluation displaying a median prediction error of −1.2% (95% CI −3.0, 0.1%). Based on simulation, Bayesian forecasting led to 65% (95% CI 62, 68%) of patients achieving a tacrolimus average steady-state concentration within a suggested acceptable range. Conclusion A theory-based population pharmacokinetic model was superior to two empirical models for prediction of tacrolimus concentrations and seemed suitable for Bayesian prediction of tacrolimus doses early after kidney transplantation.

Pharmacodynamics of mycophenolic acid in CD4+ cells: a single-dose study of IMPDH and purine nucleotide responses in healthy individuals.

Mycophenolate mofetil is used in rejection prophylaxis after allograft transplantation. The highly variable pharmacokinetics and pharmacodynamics (PD) of the active moiety mycophenolic acid (MPA) render this drug attractive for therapeutic monitoring. The aim of this study was to characterize the exposure-response relationship for MPA to guide future strategies for individualized therapy based on PD monitoring. A single-dose (100, 250, 500, and 1000 mg mycophenolate mofetil) crossover exposure-response study of MPA PD in CD4+ cells was performed in 5 healthy individuals. The activity of inosine 5′-monophosphate dehydrogenase (IMPDH) at time 0 ranged from 1.2 to 7.2 pmol per 106 cells/min. IMPDH was strongly inhibited by MPA; MPA EC50 (concentration required for 50% inhibition) of 2.3 mg/L was determined by a pooled data analysis. Decreased IMPDH gene expression was associated with the exposure to MPA. There were no immediate reductions of guanine nucleotides. On the contrary, a trend toward increased guanosine triphosphate was observed. IMPDH activity AUC0-12h approached maximum reduction at MPA AUC0-12h 22 mg·h/L (corresponding to the 500 mg dose), whereas plasma concentrations exceeding approximately 6 mg/L did not further increase the IMPDH inhibition. The results suggest that guanine nucleotides in circulating lymphocytes may not serve as immediate response biomarkers to MPA. Strategies for preventing over- or underexposure to MPA may be developed by means of IMPDH activity combined with MPA concentration measurement.

Mycophenolate pharmacokinetics and pharmacodynamics in belatacept treated renal allograft recipients – a pilot study

BackgroundMycophenolic acid (MPA) is widely used as part of immunosuppressive regimens following allograft transplantation. The large pharmacokinetic (PK) and pharmacodynamic (PD) variability and narrow therapeutic range of MPA provide a potential for therapeutic drug monitoring. The objective of this pilot study was to investigate the MPA PK and PD relation in combination with belatacept (2nd generation CTLA4-Ig) or cyclosporine (CsA).MethodsSeven renal allograft recipients were randomized to either belatacept (n = 4) or cyclosporine (n = 3) based immunosuppression. Samples for MPA PK and PD evaluations were collected predose and at 1, 2 and 13 weeks posttransplant. Plasma concentrations of MPA were determined by HPLC-UV. Activity of inosine monophosphate dehydrogenase (IMPDH) and the expressions of two IMPDH isoforms were measured in CD4+ cells by HPLC-UV and real-time reverse-transcription PCR, respectively. Subsets of T cells were characterized by flow cytometry.ResultsThe MPA exposure tended to be higher among belatacept patients than in CsA patients at week 1 (P = 0.057). Further, MPA concentrations (AUC0–9 h and C0) increased with time in both groups and were higher at week 13 than at week 2 (P = 0.031, n = 6). In contrast to the postdose reductions of IMPDH activity observed early posttransplant, IMPDH activity within both treatment groups was elevated throughout the dosing interval at week 13. Transient postdose increments were also observed for IMPDH1 expression, starting at week 1. Higher MPA exposure was associated with larger elevations of IMPDH1 (r = 0.81, P = 0.023, n = 7 for MPA and IMPDH1 AUC0–9 h at week 1). The maximum IMPDH1 expression was 52 (13–177)% higher at week 13 compared to week 1 (P = 0.031, n = 6). One patient showed lower MPA exposure with time and did neither display elevations of IMPDH activity nor IMPDH1 expression. No difference was observed in T cell subsets between treatment groups.ConclusionThe significant influence of MPA on IMPDH1 expression, possibly mediated through reduced guanine nucleotide levels, could explain the elevations of IMPDH activity within dosing intervals at week 13. The present regulation of IMPDH in CD4+ cells should be considered when interpreting measurements of IMPDH inhibition.