Compartmental pharmacokinetics and tissue distribution of the antifungal echinocandin lipopeptide micafungin (FK463) in rabbits.

The plasma pharmacokinetics and tissue distribution of the novel antifungal echinocandin-like lipopeptide micafungin (FK463) were investigated in healthy rabbits. Cohorts of three animals each received micafungin at 0.5, 1, and 2 mg/kg of body weight intravenously once daily for a total of 8 days. Serial plasma samples were collected on days 1 and 7, and tissue samples were obtained 30 min after the eighth dose. Drug concentrations were determined by validated high-performance liquid chromatographic methods. Plasma drug concentration data were fit to a two-compartment pharmacokinetic model, and pharmacokinetic parameters were estimated using weighted nonlinear least-square regression analysis. Micafungin demonstrated linear plasma pharmacokinetics without changes in total clearance and dose-normalized area under the concentration-time curve from 0 h to infinity. After administration of single doses to the rabbits, mean peak plasma drug concentrations ranged from 7.62 microg/ml at 0.5 mg/kg to 16.8 microg/ml at 2 mg/kg, the area under the concentration-time curve from 0 to 24 h ranged from 5.66 to 21.79 microg x h/ml, the apparent volume of distribution at steady state ranged from 0.296 to 0.343 liter/kg, and the elimination half-life ranged from 2.97 to 3.20 h, respectively. No significant changes in pharmacokinetic parameters and no accumulation was noted after multiple dosing. Mean tissue micafungin concentrations 30 min after the last of eight daily doses were highest in the lung (2.26 to 11.76 microg/g), liver (2.05 to 8.82 microg/g), spleen (1.87 to 9.05 microg/g), and kidney (1.40 to 6.12 microg/g). While micafungin was not detectable in cerebrospinal fluid, the concentration in brain tissue ranged from 0.08 to 0.18 microg/g. These findings indicate linear disposition of micafungin at dosages of 0.5 to 2 mg/kg and achievement of potentially therapeutic drug concentrations in plasma and tissues that are common sites of invasive fungal infections.

Safety, tolerance, and pharmacokinetics of high-dose liposomal amphotericin B (AmBisome) in patients infected with Aspergillus species and other filamentous fungi: maximum tolerated dose study.

We conducted a phase I-II study of the safety, tolerance, and plasma pharmacokinetics of liposomal amphotericin B (L-AMB; AmBisome) in order to determine its maximally tolerated dosage (MTD) in patients with infections due to Aspergillus spp. and other filamentous fungi. Dosage cohorts consisted of 7.5, 10.0, 12.5, and 15.0 mg/kg of body weight/day; a total of 44 patients were enrolled, of which 21 had a proven or probable infection (13 aspergillosis, 5 zygomycosis, 3 fusariosis). The MTD of L-AMB was at least 15 mg/kg/day. Infusion-related reactions of fever occurred in 8 (19%) and chills and/or rigors occurred in 5 (12%) of 43 patients. Three patients developed a syndrome of substernal chest tightness, dyspnea, and flank pain, which was relieved by diphenhydramine. Serum creatinine increased two times above baseline in 32% of the patients, but this was not dose related. Hepatotoxicity developed in one patient. Steady-state plasma pharmacokinetics were achieved by day 7. The maximum concentration of drug in plasma (C(max)) of L-AMB in the dosage cohorts of 7.5, 10.0, 12.5, and 15.0 mg/kg/day changed to 76, 120, 116, and 105 microg/ml, respectively, and the mean area under the concentration-time curve at 24 h (AUC(24)) changed to 692, 1,062, 860, and 554 microg x h/ml, respectively, while mean CL changed to 23, 18, 16, and 25 ml/h/kg, respectively. These data indicate that L-AMB follows dose-related changes in disposition processing (e.g., clearance) at dosages of >or=7.5 mg/kg/day. Because several extremely ill patients had early death, success was determined for both the modified intent-to-treat and evaluable (7 days of therapy) populations. Response rates (defined as complete response and partial response) were similar for proven and probable infections. Response and stabilization, respectively, were achieved in 36 and 16% of the patients in the modified intent-to-treat population (n = 43) and in 52 and 13% of the patients in the 7-day evaluable population (n = 31). These findings indicate that L-AMB at dosages as high as 15 mg/kg/day follows nonlinear saturation-like kinetics, is well tolerated, and can provide effective therapy for aspergillosis and other filamentous fungal infections.

Pharmacokinetics, excretion, and mass balance of 14C after administration of 14C-cholesterol-labeled AmBisome to healthy volunteers.

Amphotericin B (AmB) in small unilamellar liposomes (AmBisome) provides higher plasma concentrations and greater safety than the conventional deoxycholate formulation. The authors compared the disposition of the liposome's drug and cholesterol components by measuring AmB and radioactivity in plasma, urine, and feces for 1 week after a single 2-hour infusion of 14C-cholesterol-labeled AmBisome (2 mg/kg, 1 microgCi/kg) in healthy adults (4 males, 1 female). The plasma profile of 14C-cholesterol differed from that of AmB, lacking an initial rapid disappearance phase, having a lower total clearance, and having a volume of distribution (0.13 L/kg) close to that of the plasma compartment. The biphasic disappearance and long plasma half-life (147 h) of 14C-cholesterol were similar to those of other low-clearance liposomes. This and the low clearance of 14C-cholesterol from the plasma compartment suggest that it served as a liposome marker. The plasma drug-lipid ratio fell during the study, showing that AmB was cleared from plasma more rapidly than cholesterol or liposomes and suggesting that the composition of the liposomes changed over time. 14C-radioactivity was recovered mainly in the feces (9.5% of dose), consistent with the catabolism of cholesterol to bile salts. Combined fecal and renal clearances were < 18% of total clearance, suggesting that most of the liposomal drug and lipid remained in the body 1 week after dosing. Thus, AmBisome remains in the circulation for an extended period of time while releasing AmB, resulting in its markedly altered pharmacokinetic and safety profiles.

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.

Quantitation of free and total amphotericin B in human biologic matrices by a liquid chromatography tandem mass spectrometric method.

Amphotericin B remains the standard of care for the treatment of invasive and disseminated fungal infections. Various lipid-based formulations of amphotericin B have been developed to improve its therapeutic index by decreasing toxicity. Previous bioanalytic methods using microbial inhibition or high-pressure liquid chromatography quantified total amphotericin B (free, plasma protein-bound, and lipid-complexed). Sensitivity of this method with a low limit of quantitation of 0.05 microg/mL was inadequate to determine free (unbound) amphotericin B. A sensitive LC/MS/MS method was developed to determine the total amphotericin B value in human plasma and other biologic matrices and the free amphotericin B concentration in plasma. For determination of total plasma amphotericin B concentrations, the sample was diluted and injected onto the LC/MS/MS. For total amphotericin B in other matrices and free amphotericin B in plasma, solid-phase extraction was used. Natamycin served as an internal standard. A PE Sciex API 3000 (Sciex; Concord, Ontario, Canada) was used to assess free amphotericin B in plasma ultrafiltrate determination and an API 3+ for the other matrices, with electrospray interfaced to a C18 analytic column. The low limit of quantitation was 1 ng/mL for ultrafiltrate. For total amphotericin B, the low limits were 2 microg/mL for plasma, 0.05 microg/mL for urine, and 0.4 microg/mL for fecal homogenate. The methods were validated to show the standard range linearity, sensitivity, selectivity, accuracy, precision, and stability of amphotericin B in the matrices tested.

Biodistribution of 4-[(14)C]cholesterol-AmBisome following a single intravenous administration to rats.

A biodistribution study of 4-[(14)C]cholesterol-AmBisome; a unilamellar liposomal preparation of amphotericin B was conducted to support a radiolabeled human study. The radioactive plasma concentration profile (as measured in microg-Eq/ml of cholesterol) was best fit to a sum of three exponentials that yielded alpha-, beta-, and gamma-half-life estimates of 3.0 +/- 0.3, 11.8 +/- 3.7, and 113.4 +/- 32.4 h, respectively. Clearance and the steady state volume of distribution were 4.9 +/- 0.2 ml/h/kg and 341 ml/kg. Recovery data collected up through 96 h demonstrated mass balance and indicated that although the elimination profile in both urine and feces were incomplete, the dominant route of elimination (<2% in urine versus 33% in feces) was feces, presumably via biliary excretion of intact liposome and/or cholesterol. The liver, spleen, and lungs, organs of the reticuloendothelial system known for their rapid uptake of liposomes, presented with the highest levels of radioactivity. Levels in the kidney were 15% of that found in the liver and lungs.

Effect of time of meal consumption on bioavailability of a single oral 5 mg tacrolimus dose.

Tacrolimus (FK506, Prograf) is marketed for the prophylaxis of organ rejection following allogenic liver or kidney transplantation. This study investigated the effect of timing of a standardized breakfast meal on both the rate and extent of tacrolimus absorption following a single 5 mg oral dose. The protocol used a randomized, open-label, four-period, four-treatment, four-sequence crossover design in 16 healthy, nonsmoking, drug-free male subjects between the ages of 22 and 45 years who were within 15% of their ideal body weight. The four treatments were the following: (A) fasting for 10 hours, (B) ingestion 1 hour before breakfast, (C) ingestion immediately following consumption of the breakfast, and (D) ingestion 1.5 hours after beginning consumption of the breakfast. The breakfast, which was consumed over 15 minutes, contained 848 kcal, with 30%, 16%, and 54% of calories derived from fat, protein, and carbohydrate, respectively. Tacrolimus absorption in the fasting state provided the greatest relative bioavailability (p < 0.05 compared with all other three treatments). AUC(0-infinity)) averaged 312, 276, 205, and 203 ng x h/mL for treatments A, B, C and D, respectively. In contradistinction to taking the drug 1 hour prior to a meal, which had a relatively minor impact on the relative extent of absorption (approximately 12%) compared to the fasting state, ingestion of tacrolimus immediately after a meal (treatment C) or 1.5 hours subsequent to a meal (treatment D) had a more pronounced influence. Mean AUC(0-infinity) ratios (fasting to either postmeal treatments) were approximately 1.5, indicating that absorption extent was considerably reduced by ingesting tacrolimus capsules immediately after eating or 1.5 hours thereafter. Absorption was also prolonged following drug ingestion after a meal, as indicated by a mean tmax value in the fasting state of 1.84 hours, relative to 3.41 hours (immediately aftermeal, p = 0.0035) and 3.22 hours (1.5 hours postmeal, p = 0.0094). The only discernable difference in parameters between treatments C and D was with Cmax, with values of 7.19 and 9.04 ng/mL, respectively, but was not statistically significantly different (p = 0.231). Based on these results and those from a prior study, it is recommended that under therapeutic conditions, oral tacrolimus be administered in a consistent manner, both with respect to the type of meal as well as timing of ingestion relative to consumption of the meal.

The pharmacokinetics and metabolic disposition of tacrolimus: a comparison across ethnic groups.

OBJECTIVE: Our objective was to compare the intravenous and oral pharmacokinetics of tacrolimus among subjects of three different ethnic backgrounds, African American, white, and Latin American. METHODS: Ten African American, 12 white, and 12 Latin American subjects received intravenous and oral tacrolimus in an open-label, two-period, parallel group study. All of the subjects received intravenous tacrolimus (0.015 mg/kg) as a constant infusion over 4 hours and oral tacrolimus capsules (5 mg) as single doses in randomized order. Concentrations of tacrolimus and its metabolites were measured in whole blood with the use of a validated HPLC-mass spectrometry assay. RESULTS: There were no significant differences in pharmacokinetic parameters among the three study groups after intravenous administration of the drugs. After oral administration, the tacrolimus maximum concentration was significantly lower (P < .01) in the African American subjects (20.8 microg/L) than in the white subjects (37.8 microg/L) and Latin American subjects (33.0 microg/L). Absolute bioavailability was significantly lower (P = .01) in the African American subjects (11.9%) and in the Latin American subjects (14.4%) than in the white subjects (18.8%). After the oral dose, the area under the plasma concentration-time curve was lower in the African American subjects (179 microg/L x h, geometric mean) than in the white (293 microg/L x h) and Latin American subjects (239 microg/L x h, differences not statistically significant). Maximum concentration (P < .02) and area under the plasma concentration-time curve (not statistically significant) of the main tacrolimus metabolite 13-O-desmethyl tacrolimus was lower in the African American subjects than in the white and Latin American subjects. CONCLUSIONS: Significant differences in tacrolimus pharmacokinetics exist among the three different ethnic groups. Our results indicate that this may result from differences in intestinal CYP3A or P-glycoprotein activities.

Effect of low- and high-fat meals on tacrolimus absorption following 5 mg single oral doses to healthy human subjects.

Tacrolimus (FK506, Prograf) is a macrolide lactone antibiotic widely used by the oral route for the prophylaxis of organ rejection in patients who have received allogenic liver or kidney transplants. This study investigated the influence of a high- versus a low-fat meal, relative to the fasting state (three treatments total), on the rate and extent of tacrolimus absorption following a single 5 mg oral dose. The protocol employed a three-period, randomized, crossover design employing 5 x 1 mg capsules in 15 healthy male nonsmoking, drug-free volunteers, 20 to 45 years of age, who were within 15% of their ideal body weight. Food had a clinically significant effect in reducing relative bioavailability, as well as slowing absorption, but did not affect terminal exponential half-life (approximately 34 hours). Mean maximum tacrolimus blood concentration (Cmax) values were 25.6, 5.88, and 9.03 ng/mL for the fasting, high-fat, and low-fat treatments, respectively; mean area under the blood concentration-time curve (AUC(0-infinity) values were 272, 181, and 201 (ng/mL)-h, respectively; and mean time of Cmax (tmax) values were 1.37, 6.47, and 3.20 hours, respectively. Differences in parameters between the fasting and each fed treatment were statistically significantly different (p < 0.05). Statistically significant differences also existed in tmax between the two meals. Results also indicated the safety of single 5 mg oral tacrolimus doses administered to healthy volunteers.

Nonclinical and early clinical development of tacrolimus ointment for the treatment of atopic dermatitis.

Tacrolimus ointment, formulated for the treatment of atopic dermatitis, is the first in a class of topical immunomodulators. Its mechanism of action is based on calcineurin inhibition, which results in suppression of antigen-specific T-cell activation and inhibition of inflammatory cytokine release. Animal and human studies have shown that topically applied tacrolimus is minimally absorbed into the systemic circulation, the fraction that is absorbed is extensively distributed, and tacrolimus does not accumulate in tissues following repeated topical application. In addition, tacrolimus ointment is not inherently irritating, sensitizing, phototoxic, or photoallergenic when applied to intact skin. Unlike some topical corticosteroids, tacrolimus ointment does not cause a decrease in collagen synthesis or skin thickness, nor does it produce skin abnormalities or depigmentation. In animal studies, repeated daily application of tacrolimus ointment up to 1 year is associated with dermal findings similar to those following vehicle application (mild to moderate dermal irritation and microscopic findings of acanthosis, hyperkeratosis, and superficial inflammation). In a 52-week study with Yucatan micropigs, no noteworthy macroscopic or microscopic changes (either dermal or systemic) related to the application of tacrolimus ointment (0.03% to 0.3% concentrations) were observed. Tacrolimus ointment was shown to be safe and effective in phase 2 and early phase 3 studies. Significant improvements in atopic dermatitis were observed in the majority of patients treated with tacrolimus ointment. The most common adverse events associated with its use were a transient burning sensation and pruritus at the site of application. Blood tacrolimus concentrations were below the limit of quantitation in most patients.

Tacrolimus pharmacology and nonclinical studies: from FK506 to protopic.

Tacrolimus (FK506) is a calcineurin inhibitor with potent immunomodulating properties. It has been marketed worldwide since 1993-1994 for the rejection of liver and kidney transplants (Prograf). The pharmacologic properties of tacrolimus resulted in its development as an ointment for the treatment of atopic dermatitis. An outline of nonclinical pharmacology studies that provided a rationale for this development is presented. The key nonclinical toxicology-safety studies that supported clinical efficacy/safety trials are also discussed. Taken collectively, these studies contributed to the marketing approval of 0.03% and 0.1% tacrolimus ointment (Protopic) as a first in class treatment for atopic dermatitis.

Compromised kidney graft rejection response in Vervet monkeys after withdrawal of immunosuppressants tacrolimus and sirolimus.

BACKGROUND: In nonprimates, organ allografts are often not rejected after withdrawal of immunosuppression. In this study, we examined whether such a phenomenon also occurs in primates. METHODS: Vervet monkeys were transplanted with renal allografts and treated for 60 days with tacrolimus, or tacrolimus plus sirolimus. The drugs were totally withdrawn on day 61. The survival of the monkeys was monitored, and their response to donor- or third party-derived alloantigens was examined in vivo and in vitro. RESULTS: The majority (80-100%) of the grafts survived for at least additional 30 days with no signs of acute rejection. The compromised rejection is donor-specific, because recipient monkeys failed to reject a donor-derived skin graft, but a third-party skin graft was rejected. In vitro mixed lymphocyte reaction and interleukin-2 production in the mixed lymphocyte reaction between the recipients and their donors or between the recipients and a third party had no discernable patterns, and thus did not reflect the in vivo status of the immune system. Although the recipients could not reject the graft acutely after drug withdrawal, the kidney grafts and the donor-derived skin grafts had pathological findings of chronic rejection. CONCLUSIONS: The rejection response of the monkeys to an established graft after withdrawal of immunosuppression is compromised. The compromised rejection is specific and is not due to a permanent alteration of the immune system by the initial drug treatment. The allografts are not inert but have low levels of interaction with the recipient immune system.

Effect of tacrolimus (FK506) and sirolimus (rapamycin) mono- and combination therapy in prolongation of renal allograft survival in the monkey.

BACKGROUND: Our previous studies confirmed that tacrolimus (FK506) and sirolimus [rapamycin (RAPA)], in combination, are not antagonistic but are synergistic in the prolongation of heart and small bowel grafts in the rodent. The aim of this study was to confirm further the synergistic effect of combined FK506 and RAPA in the more clinically relevant model, kidney transplantation in monkeys. METHODS: A total of 60 male Vervet monkeys were randomly assigned to 10 groups (n> or =5). Monkeys with renal allografts were treated with different doses of FK506 and/or RAPA orally for 60 days. Graft survival, body weight, clinical biochemistry determinations, oral glucose tolerance test, trough levels of the two drugs, and histopathology were investigated. RESULTS: Low doses of FK506 (1 or 4 mg/kg) combined with RAPA (0.5 mg/kg) produced synergistic effect in the prolongation of renal graft survival [combination index (CI) = 0.292, 0.565]. There were no additive or synergistic drug-associated toxicities such as hyperglycemia, nephrotoxicity, and hyperlipidemia. There also was no pharmacological antagonism. CONCLUSION: Concomitant therapy of low-dose (drug-optimal) FK506 and RAPA produced a synergistic effect in the prolongation of kidney allograft survival in Vervet monkeys without additive drug-associated toxicities.

Coadministration of tacrolimus and mycophenolate mofetil in stable kidney transplant patients: pharmacokinetics and tolerability.

The tolerance and pharmacokinetics (PK) of tacrolimus (T) by the addition of mycophenolate mofetil (MMF) in stable kidney transplant patients (6/group) on long-term tacrolimus-based therapy were investigated. Patients received combination T and MMF therapy at three MMF doses: 1, 1.5, and 2 g/day administered twice daily. A 12-hour blood PK profile for T was obtained prior to MMF dosing; concomitant 12-hour profiles for T, mycophenolic acid (MPA), and mycophenolic acid glucuronide (MPAG) were obtained after 2 weeks of administration. Tolerance was monitored through 3 months. The intra- and intergroup PK of T were variable. The mean AUC0-12 of T for each group was increased after 2 weeks of concomitant MMF administration, but the increase was not statistically significant. Both drugs were well tolerated. Gastrointestinal events were of interest as such have been attributed to both T and MMF. Events reported were diarrhea, nausea, dyspepsia, and vomiting. Other common adverse events were headache, hypomagnesemia, and tremors. Most were mild, although a few were considered to be moderate. There was no apparent relationship between the incidence of any adverse event and MMF treatment group. In the present study, the coadministration of T and MMF did not significantly alter T pharmacokinetics.

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.

Bioequivalence of 1 and 5 mg tacrolimus capsules using a replicate study design.

Tacrolimus (FK506, Prograf) is marketed for the prophylaxis of organ rejection following allogenic liver or kidney transplantation. A previously conducted, randomized, 24-subject, crossover bioavailability study of 1 and 5 mg capsules (one period each) failed to demonstrate bioequivalence. A single-dose, four-period, four-sequence, randomized, crossover, replicate study (N = 32) was therefore used to evaluate the bioequivalence of the marketed 1 and 5 mg capsules in healthy volunteers. Tacrolimus blood concentrations were measured serially over 72 hours using a commercially available ELISA assay. Noncompartmental pharmacokinetic parameters were determined. Ninety percent CIs of log-transformed parameter ratios were 90.5-101.9, 87.1-101.7, and 89.7-103.8 for Cmax, AUC0-t, and AUC0-infinity, respectively. Since all values were within 80% to 125%, the capsules are bioequivalent. Based on %CVs, intersubject variability was approximately two to three times greater than intrasubject variability. The safety of single 5 mg oral tacrolimus doses administered to healthy volunteers at 7-day intervals was also ascertained.

Lipid-based amphotericin B formulations: from animals to man.

Amphotericin B has been the mainstay of systemic antifungal therapy for over 30 years, despite its serious side-effects, and, although numerous alternative antifungal agents have been developed, none to date has matched the efficacy of amphotericin B. However, modern drug delivery technology has improved the safety of amphotericin B by incorporating it into lipid-based delivery systems, including liposomes. Three such formulations, based on the natural affinity of amphotericin B for lipids, are currently marketed. All increase the therapeutic index of amphotericin B, thereby allowing more aggressive treatment than is possible with the conventional product. However, they differ in structure, side-effect profiles and evidence of proven efficacy as discussed in this review.

Effects of rifampin on tacrolimus pharmacokinetics in healthy volunteers.

Tacrolimus is a marketed immunosuppressant used in liver and kidney transplantation. It is subject to extensive metabolism by CYP3A4 and is a substrate for P-glycoprotein-mediated transport. A pharmacokinetic interaction with rifampin, an antituberculosis agent and potent inducer of CYP3A4 and P-glycoprotein, and tacrolimus was evaluated in six healthy male volunteers. Tacrolimus was administered at doses of 0.1 mg/kg orally and 0.025 mg/kg/4 hours intravenously. The pharmacokinetics of tacrolimus were obtained from serial blood samples collected over 96 hours, after single oral and intravenous administration prior to and during an 18-day concomitant rifampin dosing phase. Coadministration of rifampin significantly increased tacrolimus clearance (36.0 +/- 8.1 ml/hr/kg vs. 52.8 +/- 9.6 ml/hr/kg; p = 0.03) and decreased tacrolimus bioavailability (14.4% +/- 5.7% vs. 7.0% +/- 2.7%; p = 0.03). Rifampin appears to induce both intestinal and hepatic metabolism of tacrolimus, most likely through induction of CYP3A and P-glycoprotein in the liver and small bowel.

Dose linearity after oral administration of tacrolimus 1-mg capsules at doses of 3, 7, and 10 mg.

Tacrolimus is an immunosuppressant drug used for the prophylaxis of organ rejection in patients who receive allogenic liver or kidney transplants. This study investigated the relationship between tacrolimus blood concentration-time profiles after 3-, 7-, and 10-mg single oral doses were given to 18 healthy, drug-free, nonsmoking, institutionalized male volunteers. The protocol used a single-dose, 3-period, 3-treatment, nonmasked, randomized-block, complete crossover design. The 90% CIs of the ratios of dose-adjusted, mean, log-transformed values of maximum blood concentration, area under the tacrolimus blood concentration-time curve (0 to the last measurable concentration; lower limit of quantitation = 0.5 ng/mL), and area under the blood concentration-time curve (0 to 0) fell within the range of 125%, indicating dose proportionality for these parameters under experimental conditions. Power to detect a 20% difference for the 3 doses tested was 82.2%, 66.7%, and 72.8%, respectively.