Uwe Christians

Prolonged diabetes reversal after intraportal xenotransplantation of wild-type porcine islets in immunosuppressed nonhuman primates

Cell-based diabetes therapy requires an abundant cell source. Here, we report reversal of diabetes for more than 100 d in cynomolgus macaques after intraportal transplantation of cultured islets from genetically unmodified pigs without Gal-specific antibody manipulation. Immunotherapy with CD25-specific and CD154-specific monoclonal antibodies, FTY720 (or tacrolimus), everolimus and leflunomide suppressed indirect activation of T cells, elicitation of non-Gal pig-specific IgG antibody, intragraft expression of proinflammatory cytokines and invasion of infiltrating mononuclear cells into islets.

Comparison of the effects of tacrolimus and cyclosporine on the pharmacokinetics of mycophenolic acid.

Mycophenolate mofetil (MMF) is almost completely absorbed from the gut and is rapidly de-esterified into its active drug, mycophenolic acid (MPA). The main metabolite is glucuronidated MPA (MPAG), which is excreted into bile and undergoes enterohepatic recirculation. Studies in healthy volunteers treated with cholestyramine show that interruption of the enterohepatic recirculation decreases MPA exposure by approximately 40%. Published data show a difference in mycophenolic acid plasma concentrations between kidney transplant recipients treated with MMF plus cyclosporine (CsA) and those treated with MMF plus tacrolimus (TRL). However, the interpretation of these data is complicated by interpatient differences in variables that may influence MMF pharmacokinetics (e.g., underlying disease, co-medication, and time since transplantation). To understand the influence of TRL and CsA on MMF pharmacokinetics (PK) more completely, the authors eliminated confounding variables in clinical studies by performing drug interaction studies in inbred rats. To achieve a steady state, 3 groups of Lewis rats (n = 8 per group) were treated once daily with oral CsA (8 mg/kg), TRL (4 mg/kg), or placebo on days 0–6 before all rats began once-daily oral treatment with MMF (20 mg/kg) on day 7. Combined treatment with either MMF + CsA, MMF + TRL, or MMF + placebo was continued for 1 week (days 8–14). Thereafter, CsA and TRL treatments were stopped but MMF treatment was continued on days 14–21. Blood was sampled during the 24 hours subsequent to dosing on day 7 (after the first MMF dose), on day 14 (after multiple MMF doses) and on day 21 (after CsA/TRL washout). Rats in the MMF + TRL group and in the MMF + placebo group showed a second peak in the MPA-PK profiles consistent with enterohepatic recirculation of MPA. The MPA-PK profiles for the MMF + CsA–treated animals did not show a second MPA peak. On Day 14, the mean plasma MPA-AUC0–24 hours for the CsA-treated animals was significantly less than MPA exposures for rats in the MMF + TRL– and the MMF + placebo–treated groups. Furthermore, in contrast to results from other investigators, co-administration of CsA and MMF significantly increased MPAG-AUC0–24 hours. Serum creatinines did not differ among rats in the three groups. CsA but not TRL decreased MPA plasma levels and increased MPAG-AUC0–24 hours. These data suggest that CsA inhibits MPAG excretion into bile and offer an explanation for the well-known increased MPA exposure in organ transplant patients caused by conversion from CsA-to TRL-based immunosuppression.

Mechanisms of Clinically Relevant Drug Interactions Associated with Tacrolimus

The clinical management of tacrolimus, a macrolide used as immunosuppressant after transplantation, is complicated by its narrow therapeutic index in combination with inter- and intraindividually variable pharmacokinetics. As a substrate of cytochrome P450 (CYP) 3A enzymes and P-glycoprotein, tacrolimus interacts with several other drugs used in transplantation medicine, which also are known CYP3A and/or P-glycoprotein inhibitors and/or inducers. In clinical studies, CYP3A/P-glycoprotein inhibitors and inducers primarily affect oral bio-availability of tacrolimus rather than its clearance, indicating a key role of intestinal P-glycoprotein and CYP3A. There is an almost complete overlap between the reported clinical drug interactions of tacrolimus and those of cyclosporin. However, in comparison with cyclosporin, only few controlled drug interaction studies have been carried out, but tacrolimus drug interactions have been extensively studied in vitro. These results are inconsistent and are of poor predictive value for clinical drug interactions because of false negative results. P-glycoprotein regulates distribution of tacrolimus through the blood-brain barrier into the brain as well as distribution into lymphocytes. Interaction of other drugs with P-glycoprotein may change tacrolimus tissue distribution and modify its toxicity and immunosuppressive activity. There is evidence that ethnic and gender differences exist for tacrolimus drug interactions.Therapeutic drug monitoring to guide dosage adjustments of tacrolimus is an efficient tool to manage drug interactions. In the near future, progress can be expected from studies evaluating potential pharmacokinetic interactions caused by herbal preparations and food components, the exact biochemical mechanism underlying tacrolimus toxicity, and the potential of inhibition of CYP3A and P-glycoprotein to improve oral bioavailability and to decrease intraindividual variability of tacrolimus pharmacokinetics.

Accumulation of lovastatin, but not pravastatin, in the blood of cyclosporine-treated kidney graft patients after multiple doses.

To study pravastatin and lovastatin pharmacokinetic and pharmacodynamic effects and their interactions with cyclosporine (INN, ciclosporin) in kidney transplant patients after single and multiple doses.

Sirolimus (rapamycin) halts and reverses progression of allograft vascular disease in non-human primates.

Background. Current immunosuppressive protocols fail to prevent chronic rejection often manifested as graft vascular disease (GVD) in solid organ transplant recipients.Several new immunosuppressants including sirolimus, a dual function growth factor antagonist, have been discovered, but studies of drug efficacy have been hampered by the lack of a model of GVD in primates, as a prelude to clinical trials. As described earlier, we have developed a novel non-human primate model of GVD where progression of GVD is quantified by intravascular ultrasound (IVUS). Methods. Twelve cynomolgus monkeys underwent aortic transplantation from blood group compatible but mixed lymphocyte reaction-mismatched donors. To allow the development of GVD in the allograft, no treatment was administered for the first 6 weeks. Six monkeys were treated orally with sirolimus from day 45 after transplantation to day 105. Results. Progression of GVD measured as change in intimal area from day 42 to 105 was halted in sirolimus-treated monkeys compared to untreated monkeys (P <0.001, general linear model). On day 105, the intimal area±SEM was 3.7±1.0 and 6.4±0.5 mm2, respectively (P <0.05, t test). The magnitude of allograft intimal area on day 105 correlated inversely with sirolimus trough levels (R2=0.67, P <0.05). Regression of the intimal area was seen in four of six sirolimus-treated monkeys, which was significantly different from the untreated monkeys (P <0.05). Conclusions. Our results in the first non-human primate model of GVD showed that treatment with sirolimus not only halted the progression of preexisting GVD but also was associated with partial regression. Sirolimus trough blood levels were correlated with efficacy. Therefore, sirolimus has the potential to control clinical chronic allograft rejection.

Equilibrative nucleoside transporter 1 (ENT1) regulates postischemic blood flow during acute kidney injury in mice

A complex biologic network regulates kidney perfusion under physiologic conditions. This system is profoundly perturbed following renal ischemia, a leading cause of acute kidney injury (AKI) - a life-threatening condition that frequently complicates the care of hospitalized patients. Therapeutic approaches to prevent and treat AKI are extremely limited. Better understanding of the molecular pathways promoting postischemic reflow could provide new candidate targets for AKI therapeutics. Due to its role in adapting tissues to hypoxia, we hypothesized that extracellular adenosine has a regulatory function in the postischemic control of renal perfusion. Consistent with the notion that equilibrative nucleoside transporters (ENTs) terminate adenosine signaling, we observed that pharmacologic ENT inhibition in mice elevated renal adenosine levels and dampened AKI. Deletion of the ENTs resulted in selective protection in Ent1-/- mice. Comprehensive examination of adenosine receptor-knockout mice exposed to AKI demonstrated that renal protection by ENT inhibitors involves the A2B adenosine receptor. Indeed, crosstalk between renal Ent1 and Adora2b expressed on vascular endothelia effectively prevented a postischemic no-reflow phenomenon. These studies identify ENT1 and adenosine receptors as key to the process of reestablishing renal perfusion following ischemic AKI. If translatable from mice to humans, these data have important therapeutic implications.

Polymer-Free Biolimus A9-Coated Stent Demonstrates More Sustained Intimal Inhibition, Improved Healing, and Reduced Inflammation Compared With a Polymer-Coated Sirolimus-Eluting Cypher Stent in a Porcine Model

Background—Drug-eluting stents effectively reduce restenosis but may increase late thrombosis and delayed restenosis. Persistent polymer, the drug, or a combination of both could be responsible. Local delivery of Biolimus A9, a rapamycin derivative, from a polymer-free BioFreedom stent (Biosensors International) may prevent these complications. Methods and Results—We compared high-dose (HD) (225 &mgr;g/14 mm Biolimus A9) and low-dose (LD) (112 &mgr;g/14 mm Biolimus A9) BioFreedom stents with a polymer-coated sirolimus-eluting Cypher stent (SES) and a bare-metal stent (BMS) at 28 days and 180 days in an overstretch coronary mini-swine model with histomorphometric and histological analysis. At 28 days, there was a reduction in neointimal proliferation by HD, LD, and SES compared with BMS (neointimal thickness: HD, 0.080±0.032; LD, 0.085±0.038; SES, 0.064±0.037; BMS, 0.19±0.111 mm; P<0.001; BMS > HD/LD/SES). At 180 days, both BioFreedom stents were associated with reduced neointimal proliferation, whereas SES exhibited increased neointima (neointimal thickness: HD, 0.12±0.034; LD, 0.10±0.040; SES, 0.20±0.111; BMS, 0.17±0.099 mm; P<0.001; SES > HD/LD; BMS > LD). At 180 days, BioFreedom stents showed decreased fibrin and inflammation, including granuloma and giant cells, compared with SES. Conclusions—The polymer-free Biolimus A9–coated stent demonstrates equivalent early and superior late reduction of intimal proliferation compared with SES in a porcine model. After implantation of BioFreedom stent, delayed arterial healing was minimal, and there was no increased inflammation at 180 days compared with SES implantation. The use of polymer-free stents may have a potential long-term benefit over traditional polymeric-coated drug-eluting stents.

Functional interactions between P-glycoprotein and CYP3A in drug metabolism

The interaction between drug-metabolising enzymes and active transporters is an emerging concept in pharmacokinetics. In the gut mucosa, P-glycoprotein and cytochrome P450 (CYP)3A functionally interact in three ways: i) drugs are repeatedly taken up and pumped out of the enterocytes by P-glycoprotein, thus increasing the probability of drugs being metabolised; ii) P-glycoprotein keeps intracellular drug concentrations within the linear range of the metabolising capacity of CYP3A; and iii) P-glycoprotein transports drug metabolites formed in the mucosa back into the gut lumen. In comparison with the gut mucosa, in hepatocytes the spatial sequence of CYP3A and P-glycoprotein is reversed, resulting in different effects when the activity of one or both are changed. CYP3A and P-glycoprotein are both regulated by nuclear receptors such as the pregnane X receptor (PXR). There is significant genetic variability of CYP3A, P-glycoprotein and PXR and their expression and activity is dependent on coadministered drugs, herbs, food, age, hormonal status and disease. Future pharmacogenomic and pharmacokinetic studies will have to take all three components into account to allow for valid conclusions.

Ultrasound-Induced Mild Hyperthermia as a Novel Approach to Increase Drug Uptake in Brain Microvessel Endothelial Cells

AbstractPurpose. Drug delivery to the central nervous system (CNS) is limited by the blood-brain barrier (BBB). Thus, a noninvasive and reversible method to enhance BBB permeation of drugs is highly desirable. In the present work, we studied if ultrasound-induced mild hyperthermia (USHT, 0.4 watts (W)/cm2 at 41°C) can enhance drug absorption in BBB endothelial cells, and we elucidated the mechanism of USHT on cellular accumulation. Methods. To accomplish these aims, we studied the effects of hyperthermia (41°C), USHT, P-glycoprotein (P-gp) modulator (PSC 833), and combination of USHT and PSC 833 on accumulation of P-gp substrate (R123) and non-P-gp substrates (sucrose, 2-deoxyglucose, and antipyrine) in monolayers of primary bovine brain microvessel endothelial cells (BBMEC). Results. USHT, through its thermal effect, produces a significant (relative to controls; no USHT) and comparable increase in R123 accumulation with PSC 833. We also demonstrate that USHT increases permeability of hydrophobic (R123 and [14C]-antipyrine) and not hydrophilic molecules ([14C]-sucrose and 2-[3H]-deoxy-d-glucose). The enhanced permeability is reversible and size dependent, as USHT produces a much larger effect on cellular accumulation of [14C]-antitpyrine (molecular weight of 188 D) than that of R123 (molecular weight of 380.8 D). Although USHT increases membrane permeability, it did not affect P-gp activity or the activity of glucose transporters. Conclusions. Our results point to the potential use of USHT as a reversible and noninvasive approach to increase BBB permeation of hydrophobic drugs, including P-gp-recognized substrates.

Single dose of glutamine enhances myocardial tissue metabolism, glutathione content, and improves myocardial function after ischemia-reperfusion injury

BACKGROUND Myocardial ischemia and reperfusion (I/R) injury causes significant morbidity and mortality. Protection against I/R injury may occur via preservation of tissue metabolism and ATP content, preservation of reduced glutathione, and stimulation of heat shock protein (HSP) synthesis. Supplementation with glutamine (GLN) has been reported to have beneficial effects on all of these protective pathways. Thus, we hypothesized that GLN pretreatment given to the rat in vivo would protect the myocardium against I/R-induced dysfunction. METHODS GLN (0.52 g/kg, intraperitoneally, given as alanine-glutamine dipeptide), alanine alone (0.23 g/kg), or a Ringers lactate solution (control) was administered to Sprague-Dawley rats 18 hours before heart excision, perfusion, exposure to global ischemia (15 minutes) and reperfusion (1 hour). Tissue metabolites were analyzed via magnetic resonance spectroscopy. RESULTS In control and alanine-treated animals, I/R injury resulted in cardiac dysfunction, indicated by a decrease in cardiac output. Administration of GLN 18 hours before I/R injury preserved cardiac output after reperfusion. Metabolic analysis of the myocardial tissue revealed that [/R injury led to significant diminution of myocardial tissue glutamate, ATP content, accumulation of myocardial lactate, and a reduction in reduced glutathione content in control animals. GLN significantly reduced the deleterious changes in myocardial metabolism and improved reduced glutathione content. No changes in pre- or post-I/R injury HSP expression were observed after GLN administration. CONCLUSIONS These observations demonstrate that remote in vivo administration of GLN before cardiac I/R injury can improve post-I/R cardiac function. This effect may be mediated via improved myocardial metabolism and enhanced reduced glutathione content.