Population pharmacokinetics and bioavailability of motexafin gadolinium (Xcytrin) in CD1 mice following intravenous and intraperitoneal injection.

Motexafin gadolinium (Xcytrin) is an expanded porphyrin macrocyclic compound under development for the treatment of several types of cancer. Currently clinical trials and non-clinical pharmacology and toxicology studies are ongoing. The goals of this open label, four arm, non-crossover bioavailability study were to explore motexafin gadolinium pharmacokinetics, determine the i.p. bioavailability, and define a pharmacokinetic model suitable for descriptive and predictive use. Mice received one or seven daily i.v. or i.p. injections (40 mg/kg) then blood samples were collected and analyzed. Plasma concentration data were modelled using population pharmacokinetic methods and a two compartment model was the most appropriate model. The stability and predictive performance of the model were evaluated using bootstrap procedures. The accuracy of the predicted concentrations was 8.3%. Motexafin gadolinium was rapidly cleared from the plasma and although T(1/2beta) was 12.9 h there was no accumulation following seven doses. The i.p. bioavailability was 87.4% and higher plasma concentrations were sustainable for a longer period with i.p. dosing. V(c) was larger than the blood volume and the tissue compartment volume was 38% of V(c), suggesting motexafin gadolinium was not widely distributed into less well perfused tissues. The pharmacokinetic profile in this study was similar to that in oncology patients administered multiple doses of motexafin gadolinium. The unbiased model yields reliable parameter estimates and insight into the pharmacokinetics of motexafin gadolinium in mice, is suitable for both descriptive and predictive purposes, and is a valuable tool in the planning, analysis, and interpretation of pharmacology and toxicology studies in mice.

Comparative tacrolimus pharmacokinetics: normal versus mildly hepatically impaired subjects.

Tacrolimus (FK506, Prograf), marketed for the prophylaxis of organ rejection following allogenic liver or kidney transplantation, is virtually completely metabolized. The major metabolic pathways are P450 3A4-mediated hydroxylation and demethylation. Since P450 hepatic drug-metabolizing enzymes may be impaired in hepatic dysfunction, a study was conducted to characterize oral and intravenous tacrolimus pharmacokinetics in 6 patients with mild hepatic dysfunction and compared with parameters to those from normal subjects obtained in a separate study. Patients received two treatments: a single 0.020 mg/kg ideal body weight (IBW) i.v. dose infused over 4 hours and approximately 0.12 mg/kg IBW orally; normal subjects were dosed at 0.02 mg/kg 4-hour i.v. and 5 mg (0.065 mg/kg) p.o. Mean blood pharmacokinetic parameters with mild hepatic dysfunction were as follows: clearance = 0.035 L/h/kg, terminal exponential volume of distribution = 2.59 L/kg, terminal exponential half-life = 60.6 hours (i.v.), p.o. maximum blood concentration = 48.2 ng/mL, time of p.o. maximum blood concentration = 1.5 hours, and absolute bioavailability = 22.3%. The respective parameters in normal subjects were as follows: 0.040 L/h/kg, 1.91 L/kg, 34.2 hours (i.v.), 29.7 ng/mL, 1.6 hours, and 17.8%. Inasmuch as clearance and bioavailability were not substantially different from that in normal subjects, patients with mild hepatic impairment may initially be treated with conventional tacrolimus doses, with subsequent dosage adjustments based on response, toxicity, and therapeutic drug monitoring.

Safety, toxicokinetics and tissue distribution of long-term intravenous liposomal amphotericin B (AmBisome): a 91-day study in rats.

PURPOSE: Amphotericin B in small, unilamellar liposomes (AmBisome) is safer and produces higher plasma concentrations than other formulations. Because liposomes may increase and prolong tissue exposures, the potential for drug accumulation or delayed toxicity after chronic AmBisome was investigated. METHODS: Rats (174/sex) received intravenous AmBisome (1, 4, or 12 mg/kg), dextrose, or empty liposomes for 91 days with a 30-day recovery. Safety (including clinical and microscopic pathology) and toxicokinetics in plasma and tissues were evaluated. RESULTS: Chemical and histopathologic changes demonstrated that the kidneys and liver were the target organs for chronic AmBisome toxicity. Nephrotoxicity was moderate (urean nitrogen [BUN] < or = 51 mg/dl; creatinine unchanged). Liposome-related changes (vacuolated macrophages and hypercholesterolemia) were also observed. Although plasma and tissue accumulation was nonlinear and progressive (clearance and volume decreased, half-life increased with dose and time), most toxic changes occurred early, stabilized by the end of dosing, and reversed during recovery. There were no delayed toxicities. Concentrations in liver and spleen greatly exceeded those in plasma: kidney and lung concentrations were similar to those in plasma. Elimination half-lives were 1-4 weeks in all tissues. CONCLUSIONS: Despite nonlinear accumulation, AmBisome revealed predictable hepatic and renal toxicities after 91 days, with no new or delayed effects after prolonged treatment at high doses that resulted in plasma levels >200 microg/ml and tissue levels >3000 microg/g.

Safety and toxicokinetics of intravenous liposomal amphotericin B (AmBisome) in beagle dogs.

PURPOSE: Amphotericin B (AmB) in small, unilamellar liposomes (AmBisome) has an improved therapeutic index, and altered pharmacokinetics. The repeat-dose safety and toxicokinetic profiles of AmBisome were studied at clinically relevant doses. METHODS: Beagle dogs (5/sex/group) received intravenous AmBisome (0.25, 1, 4, 8, and 16 mg/kg/day), empty liposomes or vehicle for 30 days. AmB was determined in plasma on days 1, 14, and 30, and in tissues on day 31. Safety parameters included body weight, clinical chemistry, hematology and microscopic pathology. RESULTS: Seventeen of twenty animals receiving 8 and 16 mg/kg were sacrificed early due to weight loss caused by reduced food intake. Dose-dependent renal tubular nephrosis, and other effects characteristic of conventional AmB occurred at 1 mg/kg/day or higher. Although empty liposomes and AmBisome increased plasma cholesterol, no toxicities unique to AmBisome were revealed. Plasma ultrafiltrates contained no AmB. AmBisome achieved plasma levels 100-fold higher than other AmB formulations. AmBisome kinetics were non-linear, with clearance and distribution volumes decreasing with increasing dose. This, and nonlinear tissue uptake, suggest AmBisome disposition was saturable. CONCLUSIONS: AmBisome has the same toxic effects as conventional AmB, but they appear at much higher plasma exposures. AmBisome's non-linear pharmacokinetics are not associated with increased risk, as toxicity increases linearly with dosage. Dogs tolerated AmBisome with minimal to moderate changes in renal function at doses (4 mg/kg/day) producing peak plasma concentrations of 18-94 microg/mL.

AmBisome (liposomal amphotericin B): a comparative review.

AmBisome (NeXstarPharmaceuticals, San Dimas, CA) is a unilamellar liposomal formulation of amphotericin B that was recently approved for use as empirical treatment for presumed fungal infections in febrile neutropenic patients and for aspergillosis, candidiasis, and cryptococcosis infections refractory to amphotericin B. It is a small closed microscopic sphere (<100 nm in diameter) with an inner aqueous core (i.e., a true liposome). AmBisome remains as an intact sphere in vitro and for prolonged periods of time in vivo during the processes of systemic transport and pharmacologic action. As a consequence of its size and in vivo stability, AmBisome has physiochemical properties and a pharmacokinetic profile that are considerably different from those of currently available lipid-complexed amphotericin B formulations, with greatly increased area under the plasma concentration-time curve and much lower clearance at equivalent doses. AmBisome liposomes can be seen to accumulate at sites of fungal infection. Disruption of AmBisome liposomes occurs after attachment to the fungal cell wall and results in amphotericin B binding to fungal cell membrane ergosterol with subsequent cell lysis. AmBisome has been shown to penetrate the cell wall of both extracellular and intracellular forms of susceptible fungi.

Toxicological profile and pharmacokinetics of a unilamellar liposomal vesicle formulation of amphotericin B in rats.

AmBisome (ABLP) is a unilamellar liposomal preparation of amphotericin B that has demonstrated an improved safety profile compared to conventional amphotericin B. Single- and multiple-dose pharmacokinetics were determined by using noncompartmental methods for rats administered ABLP at 1, 3, 9, and 20 mg/kg/day. The toxicological profile was evaluated following 30 consecutive days of intravenous ABLP administration. Mean plasma amphotericin B concentrations reached 500 and 380 microg/ml (males and females, respectively) following 30 days of ABLP administration at 20 mg/kg. The overall apparent half-life was 11.2+/-4.5 h (males) or 8.7+/-2.2 h (females), and the overall clearance (CL) was 9.4+/-5.5 ml/h/kg (males) or 10.2+/-4.1 ml/h/kg (females). ABLP appears to undergo saturable disposition, resulting in a non-dose-proportional amphotericin B area under the curve and a lower CL at higher doses. Histopathological examination revealed dose-related transitional-cell hyperplasia in the transitional epithelium of the urinary tract (kidney, ureters, and urinary bladder) and moderate hepatocellular necrosis at the 20 mg/kg/day dose. Administration of ABLP in doses of up to 20 mg/kg/day resulted in 100-fold higher plasma amphotericin B concentrations, with significantly lower toxicity than that reported with conventional amphotericin B therapy.

Tacrolimus pharmacokinetics in BMT patients.

The pharmacokinetics of tacrolimus following its administration as monotherapy or in combination with corticosteroids or methotrexate to 31 BMT patients are presented. All patients received i.v. tacrolimus initially and were subsequently switched to p.o. dosing. Patients received methotrexate by i.v. bolus on post-transplantation days 1, 3, 6 and 11. Patients were started on i.v. corticosteroids beginning on post-transplantation day 7. The noncompartmental pharmacokinetics of tacrolimus based on whole blood concentrations were determined following the i.v. and p.o. doses and were not different at steady-state compared to a single dose. The mean terminal elimination half-life of tacrolimus was 18.2 h following i.v. administration; the total body clearance was 71 ml/h/kg, the volume of distribution was 1.67 1/kg. Co-administration of methylprednisolone or methotrexate did not significantly alter tacrolimus pharmacokinetics. The p.o. bioavailability was 31-49%. Trough blood concentrations (Cmin) at 0 h (pre-dose) and 12 h (post-dose) correlated well to AUC(0-12)indicating that, as in solid organ transplantation, Cmin was a good index of drug exposure. Correlation at 0 h (r = 0.92) and at 12 h (r = 0.93) indicate that either time point can be used for therapeutic drug monitoring in patient management.

Possible intraoperative anesthetic-sparing effect of parenteral ketorolac.

OBJECTIVE: Because the analgesic effects of ketorolac are equivalent to those of narcotic analgesics, we investigated the possibility that this non-steroidal antiinflammatory drug might also exhibit anesthetic-sparing properties similar to those described for narcotic agents. DESIGN: A nonrandomized, double-blind convenience sample. The treatment group received a preoperative dose of ketorolac 60 mg im 45 minutes prior to the induction of anesthesia. All other preoperative medications were identical. SETTING: Brooke Army Medical Center, a primary care setting. PARTICIPANTS: Six women requiring vaginal hysterectomies from American Society of Anesthesiologists class I/II, all of similar age, weight, and body surface area. OUTCOME MEASURES: End-tidal concentrations of the anesthetic gas were measured at five-minute intervals using a gas analyzer. A mean percent end-tidal concentration versus time curve was generated for each group. RESULTS: The area under the concentration curves for the anesthetic gas in the ketorolac and control group were 15.9 +/- 5.1 and 52.3 +/- 13.4, respectively (p = 0.006). CONCLUSIONS: Ketorolac exhibits an anesthetic-sparing quality similar to that observed with narcotic analgesics.