Efficacy and safety of MAS825 (anti-IL-1ß/IL-18) in COVID-19 patients with pneumonia and impaired respiratory function.

MAS825, a bispecific IL-1ß/IL-18 monoclonal antibody, could improve clinical outcomes in COVID-19 pneumonia by reducing inflammasome-mediated inflammation. Hospitalized non-ventilated patients with COVID-19 pneumonia (n = 138) were randomized (1:1) to receive MAS825 (10 mg/kg single i.v.) or placebo in addition to standard of care (SoC). The primary endpoint was the composite Acute Physiology and Chronic Health Evaluation II (APACHE II) score on Day 15 or on the day of discharge (whichever was earlier) with worst-case imputation for death. Other study endpoints included safety, C-reactive protein (CRP), SARS-CoV-2 presence, and inflammatory markers. On Day 15, the APACHE II score was 14.5 ± 1.87 and 13.5 ± 1.8 in the MAS825 and placebo groups, respectively (P = 0.33). MAS825 + SoC led to 33% relative reduction in intensive care unit (ICU) admissions, ~1 day reduction in ICU stay, reduction in mean duration of oxygen support (13.5 versus 14.3 days), and earlier clearance of virus on Day 15 versus placebo + SoC group. On Day 15, compared with placebo group, patients treated with MAS825 + SoC showed a 51% decrease in CRP levels, 42% lower IL-6 levels, 19% decrease in neutrophil levels, and 16% lower interferon-γ levels, indicative of IL-1ß and IL-18 pathway engagement. MAS825 + SoC did not improve APACHE II score in hospitalized patients with severe COVID-19 pneumonia; however, it inhibited relevant clinical and inflammatory pathway biomarkers and resulted in faster virus clearance versus placebo + SoC. MAS825 used in conjunction with SoC was well tolerated. None of the adverse events (AEs) or serious AEs were treatment-related.

Low-salt diet and cyclosporine nephrotoxicity: changes in kidney cell metabolism.

Cyclosporine (CsA) is a highly effective immunosuppressant used in patients after transplantation; however, its use is limited by nephrotoxicity. Salt depletion is known to enhance CsA-induced nephrotoxicity in the rat, but the underlying molecular mechanisms are not completely understood. The goal of our study was to identify the molecular effects of salt depletion alone and in combination with CsA on the kidney using a proteo-metabolomic strategy. Rats (n = 6) were assigned to four study groups: (1) normal controls, (2) low-salt fed controls, (3) 10 mg/kg/d CsA for 28 days on a normal diet, (4) 10 mg/kg/d CsA for 28 days on low-salt diet. Low-salt diet redirected kidney energy metabolism toward mitochondria as indicated by a higher energy charge than in normal-fed controls. Low-salt diet alone reduced phospho-AKT and phospho-STAT3 levels and changed the expression of ion transporters PDZK1 and CLIC1. CsA induced macro- and microvesicular tubular epithelial vacuolization and reduced energy charge, changes that were more significant in low-salt fed animals, probably because of their more pronounced dependence on mitochondria. Here, CsA increased phospho-JAK2 and phospho-STAT3 levels and reduced the phospho-IKKγ and p65 proteins, thus activating NF-κB signaling. Decreased expression of lactate transport regulator CD147 and phospho-AKT was also observed after CsA exposure in low-salt rats, indicating a decrease in glycolysis. In summary, our study suggests a key role for PDZK1, CD147, JAK/STAT, and AKT signaling in CsA-induced nephrotoxicity and proposes mechanistic explanations on why rats fed a low-salt diet have higher sensitivity to CsA.

The pharmacokinetics of Biolimus A9 after elution from the BioMatrix II stent in patients with coronary artery disease: the Stealth PK Study.

OBJECTIVES: This prospective, open-label multicenter study was conducted to assess the pharmacokinetics of Biolimus A9 after elution from BioMatrix II coronary stents. Recent clinical trials have demonstrated the efficacy and safety of Biolimus A9 eluted from different stent platforms. To date, the pharmacokinetics of Biolimus A9 in patients following the deployment of BioMatrix II stents has not yet been studied METHODS: BioMatrix II stents were implanted into 27 patients with coronary artery disease. The primary endpoints of the study were the systemic concentrations of Biolimus A9 after 28 days and 6 months as measured using a sensitive validated liquid chromatography-tandem mass spectrometry assay. RESULTS: The highest measured blood concentration at any time point was 394 pg/mL. At 28 days and 6 months following stent placement, 51.8 and 100% of patients, respectively, had Biolimus A9 concentrations <10 pg/mL. After 9 months, 100% of the patients were free of major cardiac adverse events (MACE). There was no Biolimus A9 toxicity, no cardiac or non-cardiac deaths, no myocardial infarctions, nor target vessel or target lesion revascularizations during the 9 months of follow-up. No case of acute, subacute, or late stent thrombosis was detected. CONCLUSIONS: Compared to other drug-eluting stents, such as Cypher, BioMatrix II results in relatively low systemic exposure, which may be explained by the ablominal coating of the Biomatrix II stent in combination with Biolimus A9's high lipophilicity.

Association of immunosuppressant-induced protein changes in the rat kidney with changes in urine metabolite patterns: a proteo-metabonomic study.

The basic mechanisms underlying calcineurin inhibitor (CI) nephrotoxicity and its enhancement by sirolimus are still largely unknown. We investigated the effects of CIs alone and in combination with sirolimus on the renal proteome and correlated these effects with urine metabolite pattern changes. Thirty-six male Wistar rats were assigned to six treatment groups (n = 4/group for proteome analysis and n = 6/group for urine (1)H NMR metabolite pattern analysis): vehicle controls, sirolimus 1 mg/kg/day, cyclosporine 10 mg/kg/day, cyclosporine 10 mg/kg/day + sirolimus 1 mg/kg/day, tacrolimus 1 mg/kg/day, tacrolimus 1 mg/kg/day + sirolimus 1 mg/kg/day. After 28 days, 24 h-urine was collected for (1)H NMR-based metabolic analysis and kidneys were harvested for 2D-gel electrophoresis and histology. Cyclosporine affected the following groups of proteins: calcium homeostasis (regucalcin, calbindin), cytoskeleton (vimentin, caldesmon), response to hypoxia and mitochondrial function (prolyl 4-hydroxylase, proteasome, NADH dehydrogenase), and cell metabolism (kidney aminoacylase, pyruvate dehydrogenase, fructose-1,6-bis phosphate). Several of the changes in protein expression, confirmed by Western blot, were associated with and explained changes in metabolite concentrations in urine. Representative examples are an increase in kidney aminoacylase expression (decrease of hippurate concentrations in urine), up regulation of pyruvate dehydrogenase and fructose-1,6-bisphosphatase, (increased glucose metabolism), and down regulation of arginine/glycine-amidino transferase (most likely due to an increase in creatinine concentrations). Protein changes explained and qualified immunosuppressant-induced metabolite pattern changes in urine.

Urine metabolites reflect time-dependent effects of cyclosporine and sirolimus on rat kidney function.

The clinical use of the immunosuppressant calcineurin inhibitor cyclosporine is limited by its nephrotoxicity. This is enhanced when combined with the immunosuppressive mTOR inhibitor sirolimus. Nephrotoxicity of both drugs is not yet fully understood. The goal was to gain more detailed mechanistic insights into the time-dependent effects of cyclosporine and sirolimus on the rat kidney by using a comprehensive approach including metabolic profiling in urine ((1)H NMR spectroscopy), kidney histology, kidney function parameters in plasma, measurement of glomerular filtration rates, the oxidative stress marker 15-F(2t)-isoprostane in urine, and immunosuppressant concentrations in blood and kidney. Male Wistar rats were treated with vehicle (controls), cyclosporine (10/25 mg/kg/day), and/or sirolimus (1 mg/kg/day) by oral gavage once daily for 6 and 28 days. Twenty-eight day treatment led to a decrease of glomerular filtration rates (cyclosporine, -59%; sirolimus, -25%). These were further decreased when both drugs were combined (-86%). Histology revealed tubular damage after treatment with cyclosporine, which was enhanced when sirolimus was added. No other part of the kidney was affected. (1)H NMR spectroscopy analysis of urine (day 6) revealed time-dependent changes of 2-oxoglutarate, citrate, and succinate concentrations. In combination with increased urine isoprostane concentrations, these changes indicated oxidative stress. After 28 days of cyclosporine treatment, urine metabonomics shifted to patterns typical for proximal tubular damage with reduction of Krebs cycle intermediates and trimethylamine-N-oxide concentrations, whereas acetate, lactate, trimethylamine, and glucose concentrations increased. Again, sirolimus enhanced these negative effects. Our results indicate that cyclosporine and/or sirolimus induce damage of the renal tubular system. This is reflected by urine metabolite patterns, which seem to be more sensitive than currently used clinical kidney function markers such as creatinine concentrations in serum. Metabolic profiling in urine may provide the basis for the development of toxicodynamic monitoring strategies for immunosuppressant nephrotoxicity.

Metabolic profiles in urine reflect nephrotoxicity of sirolimus and cyclosporine following rat kidney transplantation.

BACKGROUND: Cyclosporine and/or sirolimus impair recovery of renal transplants. This study examines the changes in urine metabolite profiles as surrogate markers of renal cell metabolism and function after cyclosporine and/or sirolimus treatment employing a rat kidney transplantation model. METHODS: Using inbred Lewis rats, kidneys were transplanted into bilaterally nephrectomized recipients followed by treatment with either CsA (cyclosporine) 10, Rapa (sirolimus) 1, CsA10/Rapa1 or CsA25/Rapa1 mg/kg/day for 7 days. On day 7, urine was analyzed by (1)H-NMR spectroscopy. Blood and kidney tissue drug concentrations, tissue high-energy compounds (including ATP, ADP) and oxidative stress markers (15-F(2t)-isoprostanes) in urine were measured by HPLC mass spectrometry. RESULTS: Changes in urine metabolites followed the order Rapa1 < CsA10 < CsA10/Rapa1 < CsA25/Rapa1. Compared with controls, CsA25/Rapa1 showed the greatest changes (creatinine -36%, succinate -57%, citrate -89%, alpha-ketoglutarate -75%, creatine +498%, trimethylamine +210% and taurine +370%). 15-F(2t)-isoprostane concentrations in urine increased in the combined immunosuppressant-treated animals ([CsA25/Rapa1]: 795 +/- 222, [CsA10/Rapa1]: 475 +/- 233 pg/mg/creatinine) as compared with controls (165 +/- 78 pg/mg creatinine). Rapa concentration in blood and tissues increased in the combined treatment (blood: 31 +/- 8 ng/ml, tissue: 1.3 +/- 0.4 ng/mg) as compared with monotherapy (blood: 14 +/- 8 ng/ml, tissue: 0.35 +/- 0.15 ng/mg). Drug blood concentrations correlated with isoprostane urine concentrations, which correlated negatively with citrate, alpha-ketoglutarate and creatinine concentrations in urine. Only CsA25/Rapa1 significantly reduced high-energy metabolite concentrations in transplant kidney tissue (ATP -55%, ADP -24%). CONCLUSION: Immunosuppressant drugs induce changes in urine metabolite patterns, suggesting that immunosuppressant-induced oxidative stress is an early event in the development of nephrotoxicity. Urine 15-F(2t)-isoprostane concentrations and metabolite profiles may be sensitive markers of immunosuppressant-induced nephrotoxicity.

Characterization of sirolimus metabolites in pediatric solid organ transplant recipients.

Potential age-dependent changes of sirolimus metabolite patterns in pediatric renal transplant recipients remain elusive. Thirteen pediatric solid organ transplant recipients (10 kidney, one combined liver-kidney, two liver, mean age 8.0 +/- 5.0 yr) underwent a sirolimus pharmacokinetic profile in steady-state with 10 samples drawn over 12 h post-intake to calculate the AUC(0-12 h). Concentrations of sirolimus and metabolite were quantified using a validated LC-MS/MS assay and metabolite structures were identified directly in blood extracts using LC-MS/iontrap. Average sirolimus AUC(0-12 h) was 64.9 +/- 29.7 ng h/mL. Median (range) AUC(0-12 h) for each metabolite (ng h/mL) was: 12-hydroxy-sirolimus 7.6 (0.2-18.8), 46-hydroxy sirolimus 3.1 (0.0-12.4), 24-hydroxy sirolimus 4.3 (0.0-12.6), piperidine-hydroxy sirolimus 3.5 (0.0-8.3), 39-O-desmethyl sirolimus 3.6 (0.0-11.3), 16-O-desmethyl sirolimus 5.0 (0.1-9.9), and di-hydroxy sirolimus 4.3 (0.0-32.5). The metabolites reached a median total AUC(0-12 h) of 60% of that of sirolimus. The range was 2.6-136%, indicating significant variability. In all, 77.5% of the metabolites were hydroxylated, while 39-O-desmethyl sirolimus accounted for only 8.4% of the AUC(0-12 h). This is clinically relevant as 39-O-desmethyl sirolimus shows 86-127% cross-reactivity with the antibody of the widely used Abbott sirolimus immunoassay. The metabolism of sirolimus in the children included in our study differed from that reported in adults, which should be considered when monitoring sirolimus exposure immunologically.

An automated, highly sensitive LC-MS/MS assay for the quantification of the opiate antagonist naltrexone and its major metabolite 6beta-naltrexol in dog and human plasma.

To support animal studies and clinical pharmacokinetic trials, we developed and validated an automated, specific and highly sensitive LC-MS/MS method for the quantification of naltrexone and 6beta-naltrexol in the same run. In human plasma, the assay had a lower limit of quantitation of only 5pg/mL. This was of critical importance to follow naltrexone pharmacokinetics during its terminal elimination phase. The assay had the following key performance characteristics for naltrexone in human plasma: range of reliable quantification: 0.005-100ng/mL (r2>0.99), inter-day accuracy (0.03ng/mL): 103.7% and inter-day precision: 10.1%. There were no ion suppression, matrix interferences or carry-over.

Greater free plasma VEGF and lower soluble VEGF receptor-1 in acute mountain sickness.

Vascular endothelial growth factor (VEGF) is a hypoxia-induced protein that produces vascular permeability, and limited evidence suggests a possible role for VEGF in the pathophysiology of acute mountain sickness (AMS) and/or high-altitude cerebral edema (HACE). Previous studies demonstrated that plasma VEGF alone does not correlate with AMS; however, soluble VEGF receptor (sFlt-1), not accounted for in previous studies, can bind VEGF in the circulation, reducing VEGF activity. In the present study, we hypothesized that free VEGF is greater and sFlt-1 less in subjects with AMS compared with well individuals at high altitude. Subjects were exposed to 4,300 m for 19-20 h (baseline 1,600 m). The incidence of AMS was determined by using a modified Lake Louise symptom score and the Environmental Symptoms Questionnaire for cerebral effects. Plasma was collected at low altitude and after 24 h at high altitude, or at time of illness, and then analyzed by ELISA for VEGF and for soluble VEGF receptor, sFlt-1. AMS subjects had lower sFlt-1 at both low and high altitude compared with well subjects and a significant rise in free plasma VEGF on ascent to altitude compared with well subjects. We conclude that increased free plasma VEGF on ascent to altitude is associated with AMS and may play a role in pathophysiology of AMS.

Domains of Pit-1 required for transcriptional synergy with GATA-2 on the TSH beta gene.

Previous studies showed that Pit-1 functionally cooperates with GATA-2 to stimulate transcription of the TSH beta gene. Pit-1 and GATA-2 are uniquely coexpressed in pituitary thyrotropes and activate transcription by binding to a composite promoter element. To define the domains of Pit-1 important for functional cooperativity with GATA-2, we cotransfected a set of Pit-1 deletions with an mTSH beta-luciferase reporter. Plasmids were titrated to express equivalent amounts of protein. A mutant containing a deletion of the hinge region between the POU and homeodomains retained the ability to fully synergize with GATA-2. In contrast, mutants containing deletions of amino acids 2-80 or 72-125 demonstrated 56 or 34% of the synergy found with the full-length protein, suggesting that these regions contributed to cooperativity. Mutants with deletions of the POU-specific or homeodomain further reduced the effect signifying the requirement for DNA binding. GST interaction studies demonstrated that only the homeodomain of Pit-1 interacted with GATA-2. Finally, several mutations between the Pit-1 and GATA-2 sites on the TSH beta promoter reduced binding for each factor and greatly reduced ternary complex formation. Thus multiple domains of Pit-1 are required for full synergy with GATA-2 and sequences between the two binding sites contribute to co-occupancy with both factors on the proximal TSH beta promoter.

A high-throughput U-HPLC-MS/MS assay for the quantification of mycophenolic acid and its major metabolites mycophenolic acid glucuronide and mycophenolic acid acyl-glucuronide in human plasma and urine.

Mycophenolic acid (MPA) is used as an immunosuppressant after organ transplantation and for the treatment of immune diseases. There is increasing evidence that therapeutic drug monitoring and plasma concentration-guided dose adjustments are beneficial for patients to maintain immunosuppressive efficacy and to avoid toxicity. The major MPA metabolite that can be found in high concentrations in plasma is MPA glucuronide (MPAG). A metabolite usually present at lower concentrations, MPA acyl-glucuronide (AcMPAG), has been implicated in some of the adverse effects of MPA. We developed and validated an automated high-throughput ultra-high performance chromatography-tandem mass spectrometry (U-HPLC-MS/MS) assay using liquid-handling robotic extraction for the quantification of MPA, MPAG, and AcMPAG in human EDTA plasma and urine. The ranges of reliable response were 0.097 (lower limit of quantitation) to 200 µg/mL for MPA and MPAG and 0.156-10 µg/mL for AcMPAG in human urine and plasma. The inter-day accuracies were 94.3-104.4%, 93.8-105.0% and 94.4-104.7% for MPA, MPAG and AcMPAG, respectively. Inter-day precisions were 0.7-7.8%, 0.9-6.9% and 1.6-8.6% for MPA, MPAG and AcMPAG. No matrix interferences, ion suppression/enhancement and carry-over were detected. The total assay run time was 2.3 min. The assay met all predefined acceptance criteria and the quantification of MPA was successfully cross-validated with an LC-MS/MS assay routinely used for clinical therapeutic drug monitoring. The assay has proven to be robust and reliable during the measurement of samples from several pharmacokinetics trials.

Randomized, double-blind, placebo-controlled, single intravenous dose-escalation study to evaluate the safety, tolerability, and pharmacokinetics of the novel coronary smooth muscle cell proliferation inhibitor Biolimus A9 in healthy individuals.

Biolimus A9 (BA9) is a novel proliferation inhibitor of coronary smooth muscle cells that has been specifically designed for coating drug-eluting stents. The goals of this study were to identify the highest safe intravenous dose of BA9, to evaluate the dose-dependent pharmacokinetics of BA9 after intravenous administration in humans, and to characterize early clinical symptoms of BA9 toxicity in healthy subjects. This phase 1 trial in healthy subjects was designed as a double-blind, placebo-controlled, randomized, ascending single-dose study. After screening and randomization, 28 volunteers received either placebo (n = 7) or BA9 (n = 21) in a double-blinded fashion. Doses from 0.0075 mg/kg were escalated to 0.25 mg/kg in 4 cohorts. BA9 concentrations were measured using liquid chromatography-tandem mass spectrometry. BA9 doses up to 0.075 mg/kg were well tolerated. Only the highest BA9 dose of 0.25 mg/kg produced reversible drug-related adverse events. The most frequent adverse events were headache, nausea, and mouth ulcers, most likely due to immunosuppression. Exposure to BA9 did not result in electrocardiographic or clinical laboratory changes. BA9 had a terminal half-life of 90.0 ± 40.0 hours (all n = 21, mean ± standard deviation), an apparent clearance from blood of 0.96 ± 1.07 L/kg/h, and a volume of distribution of 96.5 ± 72.6 L/kg.

Development and validation of a semi-automated assay for the highly sensitive quantification of Biolimus A9 in human whole blood using high-performance liquid chromatography-tandem mass spectrometry.

Drug-eluting stents are sustained-release intra-coronary devices that are usually coated with a few hundred micrograms of drug. Measuring the drugs that are released over weeks in order to assess human pharmacokinetics is a challenge that requires assays with high sensitivity. We developed and validated a semi-automated LC-MS/MS assay for the quantification of Biolimus A9, a proliferation signal inhibitor that was specifically developed for coating on drug-eluting stents in human EDTA blood. The only manual step was the addition of a zinc sulfate/methanol protein precipitation solution which included the internal standard. Samples were injected into the HPLC and extracted online. The assay had the following performance characteristics: range of reliable response 0.01-100 ng/mL (r(2)>0.99), inter-day accuracy (0.033 ng/mL): 111.7%, and inter-day precision: 8.6%. There was no ion suppression, matrix interferences or carry-over. Extracted samples were stable in the autosampler at +4 degrees C for at least 24 h and could undergo three freeze-thaw cycles. The assay, with a lower limit of detection of 333 fg/mL and a lower limit of quantitation of 10 pg/mL, was sufficiently sensitive and robust for quantifying Biolimus A9 in clinical trials after i.v. injection and after stent implantation.

Pharmacokinetics of mycophenolate mofetil and sirolimus in children.

This review summarizes the pharmacokinetics in children and youths of 2 commonly used immunosuppressive drugs, mycophenolate mofetil (MMF) and sirolimus (Sir), as presented at the IATDMCT 2007 conference. The review focuses on the developmental changes of drug disposition during childhood and adolescence. Regarding mycophenolate mofetil, the authors were unable to demonstrate age dependency of MMF in combination with cyclosporine. By contrast, there was an inverse relationship between age and the dose-normalized mycophenolate (MPA) area-under-the-time-concentration curve (AUC) in children who received concomitant tacrolimus (Tac). Dose-normalized MPA AUCs were higher than commonly observed in adult patients. It can be hypothesized that the age dependency is related to developmental changes in the expression of the UDP-glucuronosyltransferases. Sirolimus half-life and mean residence time (MRT) are shorter than in adults. Similar to that in adults, there is a profound drug-drug interaction between cyclosporine and Sir. In our own experience, Sir was started at 0.13 +/- 0.05 mg/kg/day. The average Sir AUC was 64.9 +/- 29.7 ng*h/mL. The median (range) AUC for each metabolite was as follows: 12-hydroxy-Sir, 7.6 (0.2-18.8); 46-hydroxy-Sir, 3.1 (0.0-12.4); 24-hydroxy-Sir, 4.3 (0.0-12.6); piperidine-hydroxy-Sir, 3.5 (0.0-8.3); 39-desmethyl-Sir, 3.6 (0.0-11.3); 16-desmethyl-Sir, 5.0 (0.1-9.9); and di-hydroxy-Sir, 4.3 (0.0-32.5) ng*h/mL. Of the total metabolite AUC, 77.5% was due to hydroxylated metabolites, while 39-O-desmethyl Sir (the main metabolite in adults) comprised only 8.4% of the metabolites. This is clinically relevant, as 39-O-desmethyl Sir shows 86% to 127% cross-reactivity with the Sir immunoassay. Metabolites reached a median AUC of 60% of that of Sir, but the range was 2.6% to 136%. The age dependency of Sir metabolite formation was confirmed in a human liver microsome model. On the basis of the age dependency of piperidine-hydroxy Sir, the authors postulate that the ontogeny of the drug disposition can be largely explained by developmental changes of the CYP2C8 expression. In conclusion, both Sir and MMF drug disposition vary in children and adolescents from adult patients, most likely because of developmental changes of biliary transporters and metabolic enzymes.

Toxicodynamic therapeutic drug monitoring of immunosuppressants: promises, reality, and challenges.

Although current immunosuppressive protocols have dramatically decreased acute rejection episodes, there has been less progress in terms of long-term graft survival after kidney transplantation over the last 2 decades. The key to reducing the damage to a transplanted organ as caused by chronic processes is early detection. Modern screening technologies in the fields of genetics, genomics, protein profiling (proteomics), and biochemical profiling (metabolomics) have opened new opportunities for the development of sensitive and specific diagnostic tools. Metabolic profiling appears to be a promising strategy because changes in the cell biochemistry are ultimately responsible for the histologic and pathophysiologic changes of the transplanted kidney and are most likely already detectable before histologic and pathophysiologic changes occur. Using truly no-targeted screening technologies as clinical diagnostic tools is not yet feasible, mostly because of the complexity of the data generated and the lack of algorithms to convert this information into clinically applicable information. A realistic and powerful targeted approach is the development of combinatorial biomarkers. These are biomarker patterns that typically consist of five or more individual parameters. Combined biomarker patterns confer significantly more information than a single measurement and, thus, can be expected to have better specificity and sensitivity. A series of studies in rats and healthy individuals evaluating the effects of immunosuppressants on urine metabolite patterns showed that immunosuppressant-induced changes of metabolite patterns in urine were associated with a combination of changes in glomerular filtration, changes in secretion/absorption by tubulus cells, and changes in kidney cell metabolism. These studies suggested that a combination of biomarkers that can be used for toxicodynamic therapeutic drug monitoring of immunosuppressants should include urine metabolites that constitute valid surrogate markers of these kidney functions.

Pharmacokinetics of enteric-coated mycophenolate sodium in stable liver transplant recipients.

INTRODUCTION: Mycophenolate mofetil (MMF) is one of the major immunosuppressive agents used in liver transplantation recipients. In an attempt to mitigate one of the most common side effects of MMF (gastrointestinal symptoms), enteric-coated mycophenolate sodium (EC-MPS) was developed. In this study, we report the pharmacokinetic profile of EC-MPS in stable liver transplantation recipients administered a single 720 mg dose. METHODS: Liver transplantation recipients more than one yr after transplantation were administered a single dose of 720 mg EC-MPS after which blood levels of MPA were measured at frequent intervals using a specific and validated LC-MS/MS assay. RESULTS: The characteristics of the 21 patients studied were: mean age was 55.9 yr, 13 were female, eight had hepatitis C, and 14 were on tacrolimus. The mean apparent half-life of MPA was 5.3 +/- 4.3 h, (1.0-15.7). Mean t(max) was 2.4 +/- 1.1 h (1.0-5.0). The mean area-under-curve was 45.3 +/- 23.1 microg-h/mL (17.3-90.0). Trough level concentrations (C(12 h)) showed large inter-individual variability (0-9.2 microg/mL). There was no difference in any of the pharmacokinetic parameters relative to: gender, HCV, administration of tacrolimus vs. cyclosporine or type of biliary anastomosis. CONCLUSIONS: There is a wide variation in pharmacokinetic parameters in stable, long-term liver transplantation recipients receiving a single dose of EC-MPS. These data suggest that therapeutic drug monitoring with EC-MPS may have limited utility in liver transplantation recipients.

Identification of everolimus metabolite patterns in trough blood samples of kidney transplant patients.

Everolimus is used as an immunosuppressant after organ transplantation. It is extensively metabolized, mainly by cytochrome P4503A enzymes, resulting in several hydroxylated and demethylated metabolites. The structures of these metabolites after in vitro metabolism of everolimus by human liver microsomes have recently been identified. It was the goal to elucidate the everolimus metabolite patterns in 128 trough blood samples from kidney graft patients using high-performance liquid chromatography (LC)-ion trap mass spectrometry (MS) in combination with analysis of the fragmentation patterns of the metabolites isolated from patient blood and comparison with the metabolites generated in vitro. After identification, concentrations of the metabolites were estimated using LC-MS. Relative to the everolimus concentrations in trough blood samples, metabolite concentrations were [median (range), n = 128] 46-hydroxy 44.1% (0-784%), 24-hydroxy 7.7% (0-85.6%), and 25-hydroxy 14.4% (0-155.4%); 11-Hydroxy, 12-hydroxy, 14-hydroxy, 49-hydroxy, two hydroxy-piperidine everolimus metabolites, 16-O-desmethyl, 16,39-O-didesmethyl, 16,27-O-didesmethyl, and 27,39-O-didesmethyl everolimus were also detected. However, when detectable, concentrations were consistently between the lower limit of detection (0.1 microg/L) and the lower limit of quantification (0.25 microg/L) of our LC-MS assay. In most trough blood samples, the total metabolite concentrations were between 50% and 100% of the everolimus concentrations. The clinical importance of everolimus metabolites in blood of patients including pharmacodynamics, toxicodynamics, and cross-reactivity with the antibodies of immunoassays used for therapeutic drug monitoring remains to be evaluated.

Impact of organ preservation using HTK for graft flush and subsequent storage in UW in rat kidney transplantation.

BACKGROUND: In kidney transplantation, preservation has a significant influence on organ function. Since previous reports have indicated a benefit of combining histidine-tryptophan-ketoglutarate (HTK) and University of Wisconsin (UW) solution, we evaluated the effects of initial flush with low viscosity HTK, followed by storage in UW. MATERIAL AND METHODS: Kidneys from inbred Lewis rats were procured using HTK or UW for initially perfusion and re-flushed after 30 min with either solution. In a third group, after perfusion with HTK, organs were re-flushed with UW. Organs were stored for 16-24 h (4 degrees C). Study parameters were high-energy phosphates, histology, apoptosis, recipient survival and urine excretion of 15-F2t -isoprostanes (oxidative stress marker). RESULTS: Prior to transplantation, tissue ATP/ADP concentrations were: HTK/UW > UW-only > HTK-only. In transplanted kidneys, histological damage was highest after preservation in HTK-only. Twenty-four hours after transplantation (24 h cold ischemia time - CIT), cleaved-PARP was most abundant using UW-only. 16 h of CIT resulted in higher urine concentrations of isoprostanes in the order HTK-only (368 +/- 308) > UW-only (157 +/- 105) > HTK/UW (67 +/- 26), and was lower in HTK/UW after 24 h of CIT (146 +/- 38) vs. UW-only (507 +/- 33 pg/mg creatinine). Survival (24 h CIT) was significantly reduced, and percentage of initial non-functioning (INF) kidneys highest in HTK-only (2.6 +/- 0.3 days, 100%), compared to UW-only (13 +/- 4.4 days, 75%) and HTK/UW (18.5 +/- 4.6 days, 33%). CONCLUSIONS: In long-term preservation, UW is superior over HTK. However, our results indicate that perfusion with HTK prior to storage in UW may improve the results of UW alone which is reflected by better survival, lower rate of INF, higher cellular energy conservation and a decrease of free radicals.

Development and validation of a high-throughput assay for quantification of the proliferation inhibitor ABT-578 using LC/LC-MS/MS in blood and tissue samples.

We report here a specific, automated LC/LC-MS/MS assay for the quantification of ABT-578 in human and rabbit blood and rabbit tissues for drug-eluting stent development. After protein precipitation, samples were injected into the HPLC system and extracted online using a high flow of 5 mL/min. The extracts were then backflushed onto the analytic column. The [M+Na] of ABT-578 (m/z 988.6-->369.4) and its internal standard sirolimus (m/z 936.5-->409.3) were monitored. Extraction and analysis took 4 minutes. The assay was validated following the US Food & Drug Administration guidelines. Linearity was 0.025-25 ng/mL for most matrices. In human blood, interday accuracies were 81.8% (at 0.025 ng/mL), 91.0% (1 ng/mL), and 99.5% (50 ng/mL), and interday precisions were 10.7% (0.025 ng/mL), 3.0% (1 ng/mL), and 1.8% (50 ng/mL).