Determination of a new antifungal agent, voriconazole, by multidimensional high-performance liquid chromatography with direct plasma injection onto a size-exclusion column

Quantitative determination of voriconazole by thionine reduction and its potential application in a pharmaceutical and clinical setting

Voriconazole (VCZ) is a triazolic drug used to treat serious fungal infections and invasive mycosis and has also been more recently used as a generic antifungal treatment. However, VCZ therapies can cause undesirable side effects and doses must be carefully monitored before administration to avoid or reduce severe toxic effects. Analytical techniques used to quantify VCZ are mostly based on HPLC/UV and often associated with multiple technical steps as well as expensive equipment. The present work aimed to develop an accessible and affordable spectrophotometric technique in the visible range (λ = 514 nm) for the simple quantification of VCZ. The technique was based on VCZ-induced reduction of thionine (TH, red) to leucothionine (LTH, colorless) under alkaline conditions. The reaction showed a linear correlation over the range of 1.00 μg mL^-1 to 60.00 μg mL^-1 at room temperature, the limits of detection and quantification being 1.93 μg mL^-1 and 6.45 μg mL^-1, respectively. VCZ degradation products (DPs) according to ¹H and ¹³C-NMR spectrometric determinations not only showed good agreement with the ones previously reported (DP1 and DP2 - T. M. Barbosa, G. A. Morris, M. Nilsson, R. Rittner and C. F. Tormena, RSC Adv., 2017, DOI: 10.1039/c7ra03822d), but also revealed a new degradation product (DP3). Mass spectrometry not only confirmed the presence of LTH as a result of the VCZ DP-induced TH reduction, but also revealed the formation of a novel and stable Schiff base as a reaction product between DP1 and LTH. The latter finding became significant as it stabilizes the reaction for quantification purposes, by hindering LTH ↔TH redox reversibility. This analytical method was then validated according to the ICH Q2 (R1) guidelines, and additionally, it could be demonstrated as applicable for the reliable VCZ quantification in commercially available tablets. Importantly, it also represents a useful tool for detecting toxic threshold concentrations in human plasma from VCZ-treated patients, alerting when these risky limits are exceeded. In this way, this technique independent from sophisticated equipment, highly qualifies as a low-cost, reproducible, trustable, and non-laborious alternative method for VCZ measurements from different matrices.

Assessment of greenness for the determination of voriconazole in reported analytical methods

Analytical research with adverse environmental impact has caused a severe rise in concern about the ecological consequences of its strategies, most notably the use and emission of harmful solvents/reagents into the atmosphere. Nowadays, industries are searching for the best reproducible methods. Voriconazole is a second-generation azole derivative used effectively in the treatment of Candida and Aspergillus species infections and oropharyngeal candidiasis in AIDS patients. Recently it has become the drug of choice in treating mucormycosis in several countries, which raises the need for production in large quantities. The present review deals with various recent important analytical techniques used to estimate voriconazole and its combination in pharmaceutical formulations and biological fluids. The methods show their own unique way of analyzing voriconazole in different matrices with excellent linearity, detection, and quantification limits. Additionally, this article deals with methods and solvents analyzed for their impact on the environment. This is followed by estimating the degree of greenness of the methods using various available assessment tools like analytical eco-scale, national environmental method index, green analytical procedure index, and AGREE metrics to confirm the environmental impact. The scores obtained with the evaluation tools depict the quantum of greenness for the reported methods and provide an ideal approach adopted for VOR estimation. Very few methods are eco-friendly, which shows that there is a need for the budding analyst to develop methods based on green analytical principles to protect the environment.

Determination of Voriconazole in Human Plasma Using RP-HPLC/UV-VIS Detection: Method Development and Validation; Subsequently Evaluation of Voriconazole Pharmacokinetic Profile in Pakistani Healthy Male Volunteers

In this research work, an isocratic, reversed-phase high-performance liquid chromatography-ultraviolet/visible detector method was developed for analysis of voriconazole standard (stock-solution) and in plasma samples. Optimization and validation of the method was carried out as per international guidelines. The method offered a simple liquid–liquid extraction technique, which exhibited best recovery of voriconazole along with fluconazole, i.e., internal standard. Different experimental conditions were tried and ultimately, the best outcomes were accomplished utilizing C-18 Perkin-Elmer® column with particulars of 150 mm length, 4.6 mm inner diameter and 5 μm particle size, protected by an RP-18 Perkin-Elmer® Pre-column guard cartridge with specifications of 10 μm particle size, 30 mm length and 4.6 mm inner diameter, utilizing mobile-phase of acetonitrile-water (ACN: H2O) in proportion of 60: 40 v/v, having a flow rate of 1.5 mL/min, and wavelength of 254 nm. All the analytes were observed to be separated in ≤7 min. A linear calibration curve was obtained at concentration range of 01–10 μg/mL of voriconazole. The correlation coefficient of voriconazole was observed to be 0.999, and average recovery (in percent) was 97.4%, whereas the relative standard deviation value was ≤2%. The lower limit of detection was 0.01 μg/mL, whereas, lower limit of quantification was 0.03 μg/mL, respectively. This developed method provided outstanding results of all validation parameters, i.e., recovery, accuracy, selectivity, precision and reproducibility. The method proposed for voriconazole analysis was applied effectively for further research investigation of voriconazole in human-plasma samples (to assess the pharmacokinetic parameters), pharmaceutical formulations and pharmacokinetic drug–drug interaction’s.

PHARMACOKINETICS OF ORALLY ADMINISTERED VORICONAZOLE IN AFRICAN PENGUINS (SPHENISCUS DEMERSUS) AFTER SINGLE AND MULTIPLE DOSES

Aspergillosis is a common respiratory fungal disease in African penguins ( Spheniscus demersus ) under managed care, and treatment failures with itraconazole due to drug resistance are increasingly common, leading to recent use of voriconazole. Empirical dosing with voriconazole based on other avian studies has resulted in adverse clinical drug effects in penguins. The objective of this study was to determine oral voriconazole pharmacokinetics (PK) in African penguins (n = 18). Single and once daily multiple oral doses of 5 mg/kg voriconazole were evaluated with a 4-mo washout period between trials. Plasma voriconazole concentrations were determined via high-performance liquid chromatography. Data was modeled using 3-compartamental population methodologies that supported first-order elimination. Observed mean peak concentration (1.89 μg/ml) after single dosing PK analysis was determined within the first hour following voriconazole administration. In the multiple-dose trial average plasma voriconazole concentrations were significantly higher on days 4 and 7 as compared with day 2. The mean estimates for volume of distribution (V/F) and clearance (Cl/F) for the multiple-dose study were 3.34 L and 0.18 L/hr, respectively. Monte Carlo simulations determined the median area under the curve (AUC_0-24) at 84 hr was 37.7 μg·h/ml. As this assessment was comparable with the average AUC in humans receiving the recommended human oral dosage 200 mg b.i.d., it suggests that 5 mg/kg p.o. s.i.d. could be a safe and effective regimen in African penguins for treatment of aspergillosis. However, due to potential drug accumulation and subsequent toxicity, therapeutic drug monitoring with dosage adjustments is recommended to individualize dosing.

Utility of noninvasive biomatrices in pharmacokinetic studies

Blood and plasma are the biomatrices traditionally used for drug monitoring and their pharmacokinetic profiling. Blood is the circulating fluid in contact with all organs and tissues of body and thus is the most representative fluid for measuring systemic drug levels. However, venipuncture suffers from the caveat of being an invasive technique which often makes people reluctant to participate in clinical studies. Thus, there is a need for noninvasive bio-fluids that are ethically appropriate, cost-efficient and toxicologically relevant. These alternate bio-fluids may prove clinically useful as alternatives to plasma/serum in therapeutic drug monitoring, pharmacokinetic and toxicokinetic studies, doping control in sports medicine and to monitor local adverse effects. These may be of particular interest in the case of special population groups such as neonates, children, the elderly, terminally ill patients and pregnant or lactating women, and offer the advantage of circumvention of the demand for specialized personnel for sample collection. This review describes such noninvasive bio-fluids (saliva, sweat, tears and milk) that have been considered for pharmacokinetic drug analysis, emphasizing their sample preparation, its associated difficulties and their correlation with plasma.

Investigation of the Potential Relationships Between Plasma Voriconazole Concentrations and Visual Adverse Events or Liver Function Test Abnormalities

This study investigated the relationship between plasma voriconazole concentrations (pVC) and risk of visual adverse events (VAEs) or liver function test (LFT) abnormalities using longitudinal logistic regression. Seven-day mean pVC were calculated from 2,925 plasma samples (1,053 patients); in each 7-day period, the presence or absence of VAEs/abnormal LFTs was analyzed as a binary outcome variable. There was a relationship between pVC and risk of VAE (P = .011) and a weaker, but statistically significant, association with risk of aspartate transaminase (AST), alkaline phosphatase (ALP), or bilirubin but not alanine transaminase (ALT) abnormalities. The odds ratios of LFT abnormalities per 1 mug/mL pVC increase ranged from 1.07 to 1.17. Maximum weekly occurrences were 10%, 8%, 5%, and 14% for AST, ALT, ALP, and bilirubin abnormalities, respectively. Receiver-operating characteristic curve analysis indicates that individual pVC cannot be used to predict subsequent LFT abnormalities.

Role of therapeutic drug monitoring of voriconazole in the treatment of invasive fungal infections

BACKGROUND

Voriconazole is a broad-spectrum, second-generation triazole antifungal agent with demonstrated efficacy in the treatment of invasive fungal infections caused by Aspergillus spp. and Candida spp. Given the characteristically poor prognosis of patients with invasive fungal infections and the protracted duration of treatment required, therapeutic monitoring of voriconazole is, in theory, an attractive method to optimize antifungal therapy.

OBJECTIVE

To determine the utility of therapeutic drug monitoring for voriconazole.

METHODS

A previously published decision-making algorithm was used to assess the currently available literature on therapeutic drug monitoring of voriconazole.

RESULTS

Several analytical methods can be used to quantify plasma or serum concentrations of voriconazole. Reasons for therapeutic monitoring of this drug include wide variability both within and between individuals secondary to drug properties, drug-drug interactions, and disease states. Furthermore, voriconazole follows nonlinear pharmacokinetics with saturable hepatic clearance. Another potential factor in favour of therapeutic drug monitoring for voriconazole is genetic polymorphism of CYP2C19, whereby patients who are homozygous for poor metabolism (about 19% of non-Indian Asians) can have 4-fold greater exposure to voriconazole. The concentrations of this drug are also greater in patients with hepatic impairment. Drug-drug interactions with other substrates of CYP2C9, CYP2C19, and CYP3A4 can also alter voriconazole concentrations. However, the correlations between plasma concentrations of voriconazole and its efficacy and toxicity are not well defined. Although lower and upper target thresholds of 0.25-2 mg/L and 4-6 mg/L, respectively, have been suggested, studies to date have not been appropriately designed or powered to reveal any definitive association.

CONCLUSIONS

Routine therapeutic drug monitoring of voriconazole is not recommended except in certain circumstances, such as lack of response to therapy or evidence of toxicity, in which case selective monitoring of voriconazole concentrations may be of clinical utility.

Therapeutic drug monitoring of voriconazole in children

Voriconazole is an extended-spectrum triazole antifungal with activity against a wide variety of pathogens, including Aspergillus, Candida, Cryptococcus neoformans, Fusarium, and Scedosporium. It exerts its antifungal activity by blocking the synthesis of fungal cell membranes and is considered the first-line treatment for invasive aspergillosis. Because the pharmacokinetics of voriconazole can demonstrate considerable variability, it has been suggested that monitoring plasma levels of voriconazole may play an important role in optimizing the efficacy and safety of the drug in complex patients like those at risk of or who have invasive aspergillosis. In this article, we review the criteria for therapeutic drug monitoring and assess the evidence for using plasma voriconazole concentrations to individualize doses in children.

Modulators of very low voriconazole concentrations in routine therapeutic drug monitoring

Very low voriconazole concentrations are commonly observed during therapeutic drug monitoring. Possible mechanisms include inappropriate dose selection, rapid metabolism (as a result of genetic polymorphisms or enzyme induction), and also nonadherence. We aimed to develop a method to distinguish between rapid metabolism of and nonadherence to voriconazole by quantification of voriconazole metabolites. In addition, the relevance of common genetic polymorphisms of CYP2C19 was assessed. In a retrospective study, samples with voriconazole concentrations 0.2 μg/mL or less in routine therapeutic drug monitoring (as quantified by high-performance liquid chromatography) were evaluated. Voriconazole and its N-oxide metabolite were quantified in residual blood using a highly sensitive liquid chromatography-tandem mass spectroscopy method (lower limit of quantitation = 0.03 μg/mL). Genetic polymorphisms of CYP2C19 were determined by real-time polymerase chain reaction using the hybridization probe format and the polymerase chain reaction-random fragment length polymorphism format. A total of 747 routine therapeutic drug monitoring plasma/blood samples of 335 patients treated with systemic voriconazole were analyzed and in 18.7% of all samples, voriconazole concentrations 0.2 μg/mL or less were found. In 32 samples (30 patients) with adequate dosage and timing of blood withdrawal, nonadherence was strongly suspected in seven patients because voriconazole-N-oxide concentrations were below 0.03 μg/mL, which was not observed in a reference group of 51 healthy volunteers with controlled drug intake. In 10 patients, of whom EDTA blood was available, the ultrarapid metabolizer genotype (CYP2C19*1\*17, CYP2C19*17\*17) was found in 80% and its prevalence was significantly higher as compared to a reference group (P = 0.02). In conclusion, quantification of voriconazole-N-oxide allowed for detection of suspected nonadherence in one of four patients with very low voriconazole concentrations. In the remaining patients, ultrarapid metabolism resulting from the CYP2C19*17 polymorphism appears to play a major role. Thus, in the case of voriconazole therapy failure, both nonadherence and genetic factors have to be considered.

Observational study of the clinical efficacy of voriconazole and its relationship to plasma concentrations in patients

Voriconazole is approved for treating invasive fungal infections. We examined voriconazole exposure-response relationships for patients from nine published clinical trials. The relationship between the mean voriconazole plasma concentration (C(avg)) and clinical response and between the free C(avg)/MIC ratio versus the clinical response were explored using logistic regression. The impact of covariates on response was also assessed. Monte Carlo simulation was used to estimate the relationship between the trough concentration/MIC ratio and the probability of response. The covariates individually related to response were as follows: study (P < 0.001), therapy (primary/salvage, P < 0.001), primary diagnosis (P < 0.001), race (P = 0.004), baseline bilirubin (P < 0.001), baseline alkaline phosphatase (P = 0.014), and pathogen (yeast/mold, P < 0.001). The C(avg) for 72% of the patients was 0.5 to 5.0 μg/ml, with the maximum response rate (74%) at 3.0 to 4.0 μg/ml. The C(avg) showed a nonlinear relationship to response (P < 0.003), with a lower probability at the extremes. For patients with C(avg) < 0.5 μg/ml, the response rate was 57%. The lowest response rate (56%) was seen with a C(avg) ≥ 5.0 μg/ml (18% of patients) and was associated with significantly lower mold infection responses compared to yeasts (P < 0.001) but not with voriconazole toxicity. Higher free C(avg)/MIC ratios were associated with a progressively higher probability of response. Monte Carlo simulation suggested that a trough/MIC ratio of 2 to 5 is associated with a near-maximal probability of response. The probability of response is lower at the extremes of C(avg). Patients with higher free C(avg)/MIC ratios have a higher probability of clinical response. A trough/MIC ratio of 2 to 5 can be used as a target for therapeutic drug monitoring.

Development and Validation of Stability Indicating RP-HPLC Method for Voriconazole

This study describes the development and validation of stability indicating HPLC method for voriconazole, an antifungal drug. Voriconazole was subjected to stress degradation under different conditions recommended by International Conference on Harmonization. The sample so generated was used to develop a stability-indicating high performance liquid chromatographic method for voriconazole. The peak for voriconazole was well resolved from peaks of degradation products, using a Hypersil C18 (250x4.6 mm) column and a mobile phase comprising of acetonitrile: water (40:60, v/v), at flow rate of 1 ml/min. Detection was carried out using photodiode array detector. A linear response (r > 0.99) was observed in the range of 5-25 mug/ml. The method showed good recoveries (average 100.06%) and relative standard deviation for intra and inter-day were </= 1.5 %. The method was validated for specificity and robustness also.

Comparison and evaluation of a novel bioassay and high-performance liquid chromatography for the clinical measurement of serum voriconazole concentrations

The aim of this study was to develop and validate a novel bioassay for determining serum voriconazole (VRC) concentrations and to compare its routine clinical performance with that of high-performance liquid chromatography (HPLC). The biological activity of VRC was measured by a plate diffusion assay using a VRC-hypersusceptible Candida kefyr strain. The bioassay's utility was tested by measuring steady-state VRC concentrations in 100 serum probes from VRC-treated patients. The HPLC system used solvent extraction with hexane:dichloromethane followed by reversed-phase HPLC with ultraviolet detection. The intra-day and inter-day accuracy of the bioassay was <5%, while that of HPLC was <1%. The precision (mean coefficient of variation, 3.5%) was equal for both the methods. The limit of quantification was lower for HPLC (0.2 mg l(-1)) than for the bioassay (0.5 mg l(-1)). The result of linear regression analysis was HPLC = 1.0178 (bioassay) + 0.328; R(2) = 0.88; n = 100. Results of the serum panel ranged from 0.5 to more than 8.0 mg l(-1) for the bioassay and from 0.26 to 10.1 mg l(-1) for HPLC. Especially in laboratories without access to HPLC, the bioassay may be a clinically useful tool for therapeutic drug monitoring.

Pharmacokinetics, safety, and tolerability of voriconazole in immunocompromised children

The pharmacokinetics of voriconazole in children receiving 4 mg/kg intravenously (i.v.) demonstrate substantially lower plasma exposures (as defined by area under the concentration-time curve [AUC]) than those in adults receiving the same therapeutic dosage. These differences in pharmacokinetics between children and adults limit accurate prediction of pediatric voriconazole exposure based on adult dosages. We therefore studied the pharmacokinetics and tolerability of higher dosages of an i.v.-to-oral regimen of voriconazole in immunocompromised children aged 2 to <12 years in two dosage cohorts for the prevention of invasive fungal infections. The first cohort received 4 mg/kg i.v. every 12 h (q12h), then 6 mg/kg i.v. q12h, and then 4 mg/kg orally (p.o.) q12h; the second received 6 mg/kg i.v. q12h, then 8 mg/kg i.v. q12h, and then 6 mg/kg p.o. q12h. The mean values for the AUC over the dosing interval (AUCτ) for 4 mg/kg and 6 mg/kg i.v. in cohort 1 were 11,827 and 22,914 ng.h/ml, respectively, whereas the mean AUCτ values for 6 mg/kg and 8 mg/kg i.v. in cohort 2 were 17,249 and 29,776 ng.h/ml, respectively. High interpatient variability was observed. The bioavailability of the oral formulation in children was approximately 65%. The safety profiles were similar in the two cohorts and age groups. The most common treatment-related adverse event was increased gamma glutamyl transpeptidase levels. There was no correlation between adverse events and voriconazole exposure. In summary, voriconazole was tolerated to a similar degree regardless of dosage and age; the mean plasma AUCτ for 8 mg/kg i.v. in children approached that for 4 mg/kg i.v. in adults, thus representing a rationally selected dosage for the pediatric population.

Development, validation, and routine application of a high-performance liquid chromatography method coupled with a single mass detector for quantification of itraconazole, voriconazole, and posaconazole in human plasma

We have developed and validated a high-performance liquid chromatography method coupled with a mass detector to quantify itraconazole, voriconazole, and posaconazole using quinoxaline as the internal standard. The method involves protein precipitation with acetonitrile. Mean accuracy (percent deviation from the true value) and precision (relative standard deviation percentage) were less than 15%. Mean recovery was more than 80% for all drugs quantified. The lower limit of quantification was 0.031 microg/ml for itraconazole and posaconazole and 0.039 microg/ml for voriconazole. The calibration range tested was from 0.031 to 8 microg/ml for itraconazole and posaconazole and from 0.039 to 10 microg/ml for voriconazole.

Validated LC Method for the Estimation of Voriconazole in Bulk and Formulation

Reversed phase high performance liquid chromatographic method was developed and validated for the estimation of voriconazole in bulk and formulation using prominence diode array detector. Selected mobile phase was a combination of water:acetonitrile (35:65 % v/v) and wavelength selected was 256 nm. Retention time of voriconazole was 3.95 min. Linearity of the method was found to be 0.1 to 2 mug/ml, with the regression coefficient of 0.999. This method was validated according to ICH guidelines. Quantification was done by calculating area of the peak and the detection limit and quantitation limit ware 0.026 mug/ml and 0.1 mug/ml, respectively. There was no significant difference in the intra day and inter day analysis of voriconazole determined for three different concentrations using this method. Present method can be applied for the determination of voriconazole in quality control of formulation without interference of the excipients.

Simultaneous determination of voriconazole and posaconazole concentrations in human plasma by high-performance liquid chromatography

A simple, sensitive, and selective high-performance liquid chromatographic method for the simultaneous determination of voriconazole and posaconazole concentrations in human plasma was developed and validated. Quantitative recovery following liquid-liquid extraction with diethyl ether was achieved. Linearity ranged from 0.10 to 20.0 microg/ml for voriconazole and from 0.05 to 10.0 microg/ml for posaconazole. The intra- and interday coefficients of variation were less than 8.5%, and the lower limits of quantitation were <0.05 microg/ml.

Population pharmacokinetic analysis of voriconazole plasma concentration data from pediatric studies

Voriconazole is a potent triazole with broad-spectrum antifungal activity against clinically significant and emerging pathogens. The present population pharmacokinetic analysis evaluated voriconazole plasma concentration-time data from three studies of pediatric patients of 2 to <12 years of age, incorporating a range of single or multiple intravenous (i.v.) and/or oral (p.o.) doses. An appropriate pharmacokinetic model for this patient population was created using the nonlinear mixed-effect modeling approach. The final model described voriconazole elimination by a Michaelis-Menten process and distribution by a two-compartment model. It also incorporated a statistically significant (P < 0.001) influence of the CYP2C19 genotype and of the alanine aminotransferase level on clearance. The model was used in a number of deterministic simulations (based on various fixed, mg/kg of body weight, and individually adjusted doses) aimed at finding suitable i.v. and p.o. voriconazole dosing regimens for pediatric patients. As a result, 7 mg/kg twice a day (BID) i.v. or 200 mg BID p.o., irrespective of body weight, was recommended for this patient population. At these doses, the pediatric area-under-the-curve (AUC) distribution exhibited the least overall difference from the adult AUC distribution (at dose levels used in clinical practice). Loading doses or individual dosage adjustments according to baseline covariates are not considered necessary in administering voriconazole to children.

Therapeutic drug monitoring of voriconazole

Voriconazole is a triazole antifungal developed for the treatment of life-threatening fungal infections in immunocompromised patients. The drug, which is available for both oral and intravenous administration, has broad-spectrum activity against pathogenic yeasts, dimorphic fungi, and opportunistic molds. Voriconazole has a nonlinear pharmacokinetic profile with a wide inter- and intraindividual variety. This variability is caused by many factors such as gender, age, genotypic variation, liver dysfunction, the presence of food, and so on. Another important factor influencing voriconazole's pharmacokinetic profile is drug-drug interactions with CYP450 inhibitors as well as inducers. Variability in plasma concentrations, as a result of the previously mentioned aspects, may lead to variability in efficacy or toxicity. Determination of plasma concentrations is indicated in situations to guide dosing and to individualize and improve the treatment options resulting in better therapeutic outcome or fewer side effects. In this article, we review factors influencing voriconazole pharmacokinetic profile, the data supporting exposure-effect and exposure-toxicity relationships, review the gaps in current knowledge, which make broad recommendations for therapeutic drug monitoring difficult for voriconazole, provide the indications in which therapeutic drug monitoring is reasonable based on currently available data (eg, children), and outline the ways in which this problem could be solved. We provide a summary of the problem so that further research can be conducted to address this are of clinical need.

Development and validation of an efficient HPLC method for quantification of voriconazole in plasma and microdialysate reflecting an important target site

Voriconazole is a very potent antifungal agent used to treat serious fungal infections (candidiasis); it is also the therapy of choice for aspergillosis. After standard dosing, several factors affect exposure of voriconazole, resulting in large variability and demanding further elucidation of drug distribution. For measurements at the site of action, microdialysis is considered to be an outstanding minimally invasive method. For determination of voriconazole in microdialysate and human plasma a new, efficient, reliable, and robust HPLC assay using UV detection at 254 nm has been developed and validated. After simple sample preparation using acetonitrile for plasma and for microdialysate, 20 microL were injected and separated on an RP-18 column. The chromatographic run time was less than 4 min. Overall, the assay showed high precision (CV 93.9 to 99.5%) and accuracy (RE -96.7 to +107%) for both matrices. Of the 36 drug products typically co-administered with voriconazole, none except ambroxol interfered with its peak signal, and this interference was successfully managed. In summary, the method is highly suitable for application in (pre)clinical microdialysis studies, e.g., of critically ill patients with invasive mycoses.

Determination of the antifungal agent voriconazole in human plasma using a simple column-switching high-performance liquid chromatography and its application to a pharmacokinetic study

A simple column-switching high performance liquid chromatographic (HPLC) method that does not require any complicated pretreatment has been developed to determine voriconazole in human plasma samples. An internal standard (IS) and borate buffer (pH 9.0) were added to plasma samples, which were then injected directly into the column-switching HPLC system using MAYI-ODS as a pre-column. The calibration curve for voriconazole showed good linearity in the range of 0.2-10 mug/ml in human plasma. The mean RSD (%) value of intra-day (n=6) and inter-day (n=5) precision were less than 5.4% and 8.2%, respectively. This system could make more than three hundred successive, accurate measurements when a washing step with ammonium acetate solution was added. This method was successfully applied to measure the therapeutic voriconazole level in patients' plasma, and was used in a study of voriconazole pharmacokinetics after oral administration.

Pharmacokinetic interaction between voriconazole and efavirenz at steady state in healthy male subjects

A randomized, placebo-controlled (with respect to voriconazole), 2-period, multiple-dose intragroup fixed-dose sequence study was conducted in 34 healthy male subjects to evaluate the interactions between voriconazole (triazole antifungal agent) and efavirenz (reverse transcriptase inhibitor). In period 1, subjects received 200 mg twice-daily (bid) voriconazole (n = 17) or placebo (n = 17) for 3 days (400-mg bid loading doses on day 1). In period 2, following a 7-day washout, subjects received 400 mg once-daily (qd) efavirenz alone for 10 days (days 11-20). Then efavirenz was coadministered with 200 mg bid voriconazole or placebo for the next 9 days (days 21-29). Serial plasma voriconazole and efavirenz concentrations were measured on days 3, 19, and 29, and the safety data were collected throughout the study. The 400-mg qd efavirenz dose substantially reduced the steady-state mean voriconazole area under the curve over the dosing interval (AUC0-12) by 80% (90% confidence interval [CI], 75%-84%) and peak concentration (Cmax) by 66% (90% CI, 57%-73%). The decrease in voriconazole exposure during coadministration is probably mainly due to the induction of CYP2C19 and CYP2C9 by efavirenz. The 200 mg bid voriconazole increased the steady-state mean AUC0-24 and Cmax of efavirenz by 43% (90% CI, 36%-51%) and 37% (90% CI, 29%-46%), respectively. The increase in efavirenz exposure during coadministration is probably due to the inhibition of CYP3A4 by voriconazole. Coadministration of 200 mg bid voriconazole with 400 mg (or higher) qd efavirenz is contraindicated due to the clinically significant effect of efavirenz on voriconazole pharmacokinetics.

Measurement of voriconazole in serum and plasma

OBJECTIVES

Voriconazole is an antifungal agent structurally related to fluconazole. While regular drug monitoring is not indicated in most patients, it may help guide dosing in patients with reduced hepatic/renal function, on concurrent therapy with drugs that affect CYP2C9, with altered CYP2C9 genotypes, or during adverse drug reactions. Here we describe an HPLC method for determination of voriconazole.

METHODS

Samples, calibrators and controls were extracted using a liquid/liquid extraction. Chromatographic separation achieved using gradient solvent delivery with detection at 254 nm with a run time of 10 min. Concentration was calculated by comparison of peak height ratio of the drug with that of internal standard (IS) against a standard curve.

RESULTS

The assay is linear from 0.29 to 57 micromol/L (0.1-20 microg/mL) shows good linearity (y=0.98x+0.36, r(2)=0.9978). The assay has inter- and intra-day precisions of <10%. The stability of the drugs in specimens was tested for up to 7 days at room temperature, for 30 days frozen at -20 degrees C, and through 3 freeze-thaw cycles and was found to be stable under those conditions.

CONCLUSIONS

This describes a robust method for the determination of voriconazole in serum and plasma.

Steady-state pharmacokinetic and safety profiles of voriconazole and ritonavir in healthy male subjects

Since there is a likelihood of coadministration of voriconazole and ritonavir, two studies were conducted to evaluate the potential of drug interaction. Study A was a randomized, placebo-controlled, two-period, parallel-group trial (n = 34). Study B had the same design without the placebo group (n = 17). In period 1, subjects received 200 mg voriconazole or placebo twice daily (BID) for 3 days (400 mg BID on day 1). In period 2, following a 7-day washout, subjects received ritonavir alone at 400 mg BID (study A) or 100 mg BID (study B) for 10 days (days 11 to 20), and then ritonavir was coadministered with 200 mg BID voriconazole or placebo for the next 10 days (days 21 to 30). Serial plasma samples were collected on days 3, 20, and 30, and safety data were collected throughout the study. High-dose (400 mg BID) ritonavir substantially reduced the steady-state mean voriconazole exposure (area under the concentration-time curve from 0 to 12 h [AUC(0-12)], -82%; maximum concentration [C(max)], -66%). However, the effect of low-dose (100 mg BID) ritonavir was less pronounced (AUC(0-12), -39%; C(max), -24%). The decrease in voriconazole exposure was probably due to the induction of CYP2C19 and CYP2C9 by ritonavir. It is interesting that one subject in each study exhibited the opposite effect of ritonavir on voriconazole exposure (a 2.5- to 3-fold increase), probably due to lack of CYP2C19. Voriconazole had no apparent effect on the exposure of high-dose ritonavir but slightly decreased the exposure of low-dose ritonavir (AUC(0-12), -14%; C(max), -24%). The safety profile of combination therapy was not notably different from that of voriconazole or ritonavir alone. Due to the significant effect of ritonavir on voriconazole exposure, coadministration of voriconazole with 400 mg BID ritonavir is contraindicated; coadministration with 100 mg BID ritonavir should be avoided, unless an assessment of the benefit/risk to the patient justifies the use.

Current role of LC-MS in therapeutic drug monitoring

The role of liquid chromatography coupled with mass spectrometry (LC-MS) techniques in routine therapeutic drug monitoring activity is becoming increasingly important. This paper reviews LC-MS methods published in the last few years for certain classes of drugs subject to therapeutic drug monitoring: immunosuppressants, antifungal drugs, antiretroviral drugs, antidepressants and antipsychotics. For each class of compounds, we focussed on the most interesting methods and evaluated the current role of LC-MS in therapeutic drug monitoring.

Variability of voriconazole plasma levels measured by new high-performance liquid chromatography and bioassay methods

Voriconazole (VRC) is a broad-spectrum antifungal triazole with nonlinear pharmacokinetics. The utility of measurement of voriconazole blood levels for optimizing therapy is a matter of debate. Available high-performance liquid chromatography (HPLC) and bioassay methods are technically complex, time-consuming, or have a narrow analytical range. Objectives of the present study were to develop new, simple analytical methods and to assess variability of voriconazole blood levels in patients with invasive mycoses. Acetonitrile precipitation, reverse-phase separation, and UV detection were used for HPLC. A voriconazole-hypersusceptible Candida albicans mutant lacking multidrug efflux transporters (cdr1Delta/cdr1Delta, cdr2Delta/cdr2Delta, flu1Delta/flu1Delta, and mdr1Delta/mdr1Delta) and calcineurin subunit A (cnaDelta/cnaDelta) was used for bioassay. Mean intra-/interrun accuracies over the VRC concentration range from 0.25 to 16 mg/liter were 93.7% +/- 5.0%/96.5% +/- 2.4% (HPLC) and 94.9% +/- 6.1%/94.7% +/- 3.3% (bioassay). Mean intra-/interrun coefficients of variation were 5.2% +/- 1.5%/5.4% +/- 0.9% and 6.5% +/- 2.5%/4.0% +/- 1.6% for HPLC and bioassay, respectively. The coefficient of concordance between HPLC and bioassay was 0.96. Sequential measurements in 10 patients with invasive mycoses showed important inter- and intraindividual variations of estimated voriconazole area under the concentration-time curve (AUC): median, 43.9 mg x h/liter (range, 12.9 to 71.1) on the first and 27.4 mg x h/liter (range, 2.9 to 93.1) on the last day of therapy. During therapy, AUC decreased in five patients, increased in three, and remained unchanged in two. A toxic encephalopathy probably related to the increase of the VRC AUC (from 71.1 to 93.1 mg x h/liter) was observed. The VRC AUC decreased (from 12.9 to 2.9 mg x h/liter) in a patient with persistent signs of invasive aspergillosis. These preliminary observations suggest that voriconazole over- or underexposure resulting from variability of blood levels might have clinical implications. Simple HPLC and bioassay methods offer new tools for monitoring voriconazole therapy.

Pharmacokinetic interaction between voriconazole and methadone at steady state in patients on methadone therapy

This trial was aimed to estimate the pharmacokinetic interaction between voriconazole and methadone at steady state in male patients on methadone therapy and to characterize the safety and tolerability profile during the coadministration. Twenty-three patients on individualized methadone therapy (30 to 100 mg once daily) were enrolled into this randomized, patient- and investigator-blind, placebo-controlled, parallel-group study. Methadone pharmacokinetic samples were collected from patients receiving methadone alone as the baseline before they were randomized to coadminister either 200 mg voriconazole twice daily (BID) (400-mg BID loading doses on the first day) (n = 16) or matching placebo (n = 7) for the next 5 days. Pharmacokinetic samples for methadone and voriconazole were collected on the last day of voriconazole dosing. The safety data were collected throughout the study. Voriconazole increased the steady-state exposure of pharmacologically active enantiomer (R)-methadone: the mean area under the concentration-time curve from 0 to 24 h (AUC(0-24)) was increased by 47.2% (90% confidence intervals [CI]: 37.7%, 57.4%), and the mean peak concentration (C(max)) was increased by 30.7% (90% CI: 22.2%, 39.8%). The magnitude of increase in (S)-methadone exposure was greater than that of (R)-methadone: the AUC(0-24) was increased by 103.4% (90% CI: 85.0%, 123.6%), and the C(max) was increased by 65.4% (90% CI: 52.6%, 79.2%). Methadone appeared to have no effect on the steady-state voriconazole pharmacokinetics compared to the historical data for voriconazole alone. Methadone patients receiving voriconazole showed no signs or symptoms of significant opioid withdrawal or overdose. Coadministration of 200 mg voriconazole BID with methadone was generally safe and well tolerated. Nevertheless, caution should be exercised when voriconazole is coadministered with methadone due to the increase in (R)-methadone exposure, which in turn may require a dose reduction of methadone.

Topical voriconazole as a novel treatment for fungal keratitis

Paecilomyces lilacinus is a fungal pathogen which is generally resistant to amphotericin B and certain other antifungals and is an uncommon cause of devastating fungal keratitis. In the present studies, we evaluated topical voriconazole as therapy for P. lilacinus keratitis in rabbits. Thirty eyes of 15 rabbits were studied. In five animals, the uninfected left eye was treated twice daily with voriconazole (drug control, uninfected eye). In these same animals, the right eye was infected with P. lilacinus but not treated with voriconazole (infection control eye). By day 5, the infection controls had lesions of >2.4 mm in diameter, with conjunctivitis and severe hypopyon, and were sacrificed. In the other 10 rabbits (voriconazole treatment), the right eyes were infected with P. lilacinus and treated with voriconazole beginning on day 3 after infection. Voriconazole therapy caused lesions to decrease during 8 days of therapy, after which rabbits were sacrificed (11 days postinfection). Hyphal masses were present in the control infected eyes and absent in treated infected eyes. Voriconazole was detected in all tissues of treated eyes. Topical voriconazole is effective treatment for P. lilacinus experimental keratitis, and it penetrates more deeply than the corneal tissue.

Quantification of voriconazole in plasma by liquid chromatography-tandem mass spectrometry

A convenient liquid chromatography-tandem mass spectrometry method for the quantification of the triazole antifungal agent voriconazole in plasma samples is described. Fenbuconazole is used as an internal standard. After protein precipitation, automated solid-phase extraction is applied. Electrospray ionization in the positive mode is used and the following mass transitions are recorded: voriconazole, 350-->127; and fenbuconazol, 337-->125. The analytical run time is 4 min. The response was linear from 78 to 5000 microg/L. The total coefficient of variation (n=16) was 12.6% for a low-concentration pool (143 microg/L), 4.7% for a medium-concentration pool (419 microg/L), and 5.0% for a high-concentration pool (4304 microg/L). The method is proposed for future investigations that should be performed to test the hypothesis that therapeutic drug monitoring of voriconazole is clinically useful.

Direct injection HPLC micro method for the determination of voriconazole in plasma using an internal surface reversed-phase column

A direct plasma injection liquid chromatographic method has been developed for the determination of a new triazole antifungal agent, voriconazole, using an internal surface reversed phase column. Therapeutic drug monitoring of voriconazole is relevant for patient management, especially in the case of drug-drug interaction. The method is easy to perform and requires 10 microL of a plasma sample. The chromatographic run time is less than 9 min using a mobile phase of 17:83 v/v acetonitrile-potassium dihydrogen phosphate buffer, 100 mM, pH 6.0 and UV detection at 255 nm. The fl ow rate was 1 microL/min. A linear response was observed over the concentration range 0.5-10 microg/mL (r2 = 0.977). A good accuracy (bias < or = 7.5%) was achieved for all quality controls, with intra-day and inter-day variation coefficients inferior to 6.7%. The lower limit of quantitation was 0.2 microg/mL, without interference of endogenous components. The stability of voriconazole in plasma stored at different temperatures was checked. Finally, the possibility of direct injection of plasma samples into the column permits a reduction in reagent consumption and in analytical steps, and hence in analytical error.

Pharmacokinetics and safety of intravenous voriconazole in children after single- or multiple-dose administration

We conducted a multicenter study of the safety, tolerability, and plasma pharmacokinetics of the parenteral formulation of voriconazole in immunocompromised pediatric patients (2 to 11 years old). Single doses of 3 or 4 mg/kg of body weight were administered to six and five children, respectively. In the multiple-dose study, 28 patients received loading doses of 6 mg/kg every 12 h on day 1, followed by 3 mg/kg every 12 h on day 2 to day 4 and 4 mg/kg every 12 h on day 4 to day 8. Standard population pharmacokinetic approaches and generalized additive modeling were used to construct the structural pharmacokinetic and covariate models used in this analysis. In contrast to that in adult healthy volunteers, elimination of voriconazole was linear in children following doses of 3 and 4 mg/kg every 12 h. Body weight was more influential than age in accounting for the observed variability in voriconazole pharmacokinetics. Elimination capacity correlated with the CYP2C19 genotype. Exposures were similar at 4 mg/kg every 12 h in children (median area under the concentration-time curve (AUC), 14,227 ng. h/ml) and 3 mg/kg in adults (median AUC, 13,855 ng. h/ml). Visual disturbances occurred in 5 (12.8%) of the 39 patients and were the only drug-related adverse events that occurred more than once. No withdrawals from the study were related to voriconazole. We conclude that pediatric patients have a higher capacity for elimination of voriconazole per kilogram of body weight than do adult healthy volunteers and that dosages of 4 mg/kg may be required in children to achieve exposures consistent with those in adults following dosages of 3 mg/kg.

Effect of omeprazole on the steady-state pharmacokinetics of voriconazole

AIMS

Voriconazole, a novel triazole antifungal agent, is metabolized by the cytochrome P450 isoenzymes CYP2C19, CYP2C9, and to a lesser extent by CYP3A4. Omeprazole, a proton pump inhibitor used widely for the treatment of gastric and duodenal ulcers, is predominantly metabolized by CYP2C19 and CYP3A4. The aim of this study was to determine the effects of omeprazole on the steady-state pharmacokinetics of voriconazole. A secondary objective was to characterize the pharmacokinetic profile of an oral loading dose regimen of 400 mg twice-daily voriconazole on day 1.

METHODS

This was an open, randomized, placebo-controlled, two-way crossover study of 18 healthy male volunteers. Subjects received oral voriconazole (400 mg twice daily on day 1 followed by 200 mg twice daily on days 2-9 and a single 200-mg dose on day 10) with either omeprazole (40 mg once daily) or matched placebo for 10 days. There was a minimum 7-day washout between treatment periods.

RESULTS

Mean Cmax and AUCtau of voriconazole were increased by 15%[90% confidence interval (CI) 5, 25] and 41% (90% CI 29, 55), respectively, with no effect on tmax during coadministration of omeprazole. Visual inspection of predose plasma concentrations (Cmin) indicated that steady-state plasma concentrations were achieved following the second loading dose. One subject withdrew from the study during the voriconazole + omeprazole treatment period because of treatment-related abnormal liver function test values. All other treatment-related adverse events resolved without intervention.

CONCLUSIONS

Omeprazole had no clinically relevant effect on voriconazole exposure, suggesting that no voriconazole dosage adjustment is necessary for patients in whom omeprazole therapy is initiated. Administration of a 400-mg twice-daily oral loading dose regimen on day 1 resulted in steady-state plasma levels of voriconazole being achieved following the second loading dose.

Histamine H2-receptor antagonists have no clinically significant effect on the steady-state pharmacokinetics of voriconazole

AIMS

Voriconazole, a new triazole antifungal agent, is metabolized mainly by cytochrome P450s CYP2C19 and CYP2C9, and also by CYP3A4. The aim of this open-label, placebo-controlled, randomized, three-way crossover study was to determine the effects of cimetidine and ranitidine on the steady-state pharmacokinetics of voriconazole.

METHODS

Twelve healthy male subjects received oral voriconazole 200 mg twice daily plus cimetidine 400 mg twice daily, voriconazole 200 mg twice daily plus ranitidine 150 mg twice daily, and voriconazole 200 mg twice daily plus placebo twice daily. Treatment periods were separated by at least 7 days.

RESULTS

When cimetidine was administered with voriconazole, the maximum plasma voriconazole concentration (Cmax) and the area under the plasma concentration-time curve of voriconazole (AUCtau) was increased by 18.3%[90% confidence interval (CI) 6.0, 32.0] and 22.5% (90% CI 13.3, 32.5), respectively. Concomitant ranitidine had no significant effect on voriconazole Cmax or AUCtau. Time of Cmax (tmax) elimination half-life (t 1/2) or terminal phase rate constant (kel) for voriconazole were similar in all three treatment groups. Most adverse events were mild and transitory; two subjects were withdrawn due to adverse events.

CONCLUSIONS

Coadministration of the histamine H2-receptor antagonists cimetidine or ranitidine does not affect the steady-state pharmacokinetics of voriconazole in a clinically relevant manner.

The pharmacokinetics and safety of intravenous voriconazole - a novel wide-spectrum antifungal agent

AIMS

Voriconazole is a new triazole with broad-spectrum antifungal activity against clinically significant and emerging pathogens. These studies evaluated the pharmacokinetics and safety of intravenous voriconazole in healthy male volunteers.

METHODS

Two single-blind, placebo-controlled studies were conducted. In Study A, 12 subjects were randomized to voriconazole (3 mg kg-1) or placebo, administered once daily on days 1 and 12, and every 12 h on days 3-11. In Study B, 18 subjects were randomized to voriconazole or placebo, with voriconazole being administered as a loading dose at 6 mg kg-1 twice on day 1, then at 3 mg kg-1 twice daily on days 2-9, and once at 3 mg kg-1 on day 10.

RESULTS

In both studies, the plasma concentrations of voriconazole increased rapidly following the initiation of dosing. Minimum observed plasma concentration (Cmin) values at steady state were above the in vitro minimum inhibitory concentrations (MICs) for most fungal pathogens (Cmin > 0.8 micro g ml-1). The use of a loading dose in Study B resulted in a shorter time to steady-state Cmin values than was observed in Study A. Values of the final day plasma pharmacokinetic parameters in Studies A and B were similar: maximum observed plasma concentration (Cmax) 3621 and 3063 ng ml-1; areas under the plasma concentration-time curve from time zero to the end of the dosing interval (AUCtau) 16 535 and 13 245 ng.h ml-1, and terminal elimination phase half-lives (t1/2) 6.5 and 6.7 h, respectively. On multiple dosing, voriconazole accumulated (AUCtau accumulation ratio 2.53-3.17, Study A) at a level that was not predictable from single-dose data. The mean concentration-time profiles for voriconazole in saliva were similar to those in plasma. Multiple doses of voriconazole were well tolerated and no subject discontinued from either study. Seven cases of possibly drug-related visual disturbance were reported in three subjects (Study B).

CONCLUSIONS

Administration of a loading dose of 6 mg kg-1 i.v. voriconazole on the first day of treatment followed by 3 mg kg-1 i.v. twice daily achieves steady state by the third day of dosing. This dosage regimen results in plasma levels of the drug that rapidly exceed the minimum inhibitory concentrations (MICs) against important fungal pathogens, including Aspergillus spp.

No clinically significant effect of erythromycin or azithromycin on the pharmacokinetics of voriconazole in healthy male volunteers

AIMS

The antibiotic erythromycin is a potent inhibitor of cytochrome P450 CYP3A4 metabolism. As CYP isozymes, including CYP3A4, are involved in the metabolism of the new triazole voriconazole, this study investigated the effects of multiple-dose erythromycin or azithromycin on the steady-state pharmacokinetics of voriconazole in healthy male subjects.

METHODS

In an open, randomized, parallel-group, single-centre study, 30 healthy male subjects aged 20-41 years received oral voriconazole 200 mg twice daily for 14 days plus either erythromycin (1 g twice daily on days 8-14), azithromycin (500 mg once daily on days 12-14) or placebo (twice daily on days 8-14). Only morning doses were administered on day 14. Plasma concentrations of voriconazole were measured up to 12 h postdose on days 7 and 14, and plasma pharmacokinetic parameters were calculated. Adverse events and standard laboratory test results were recorded before and throughout the study.

RESULTS

Comparison of the voriconazole Cmax day 14/day 7 ratio for the voriconazole + erythromycin group with that of the voriconazole + placebo group yielded a ratio of 107.7%[90% confidence interval (CI) 90.6, 128.0]; for the voriconazole + azithromycin group, the ratio was 117.5% (90% CI 98.8, 139.7). Comparison of the voriconazole AUCtau day 14/day 7 ratios of the voriconazole + erythromycin and voriconazole + azithromycin groups with that of the voriconazole + placebo group showed ratios of 101.2% (90% CI 89.1, 114.8) and 107.9% (90% CI 95.1, 122.4), respectively. For voriconazole tmax, the differences between the day 14-day 7 calculations for the voriconazole + erythromycin or the voriconazole + azithromycin groups and that of the voriconazole + placebo group were - 0.2 h (90% CI - 0.8, 0.3) and - 0.1 h (90% CI - 0.7, 0.5), respectively. None of these changes was considered clinically relevant. The study drugs were well tolerated by subjects in all groups; the most common study drug-related adverse events were visual disturbances, reported in all groups, and abdominal pain, present in the voriconazole + erythromycin group.

CONCLUSIONS

Coadministration of erythromycin or azithromycin does not affect the steady-state pharmacokinetics of voriconazole in a clinically relevant manner in healthy male subjects.

No clinically significant pharmacokinetic interactions between voriconazole and indinavir in healthy volunteers

AIMS

Voriconazole is a new triazole antifungal agent, and is metabolized by the cytochrome P450 isoenzymes CYP2C9, CYP2C19 and to a lesser extent by CYP3A4. Protease inhibitors, such as indinavir, are also metabolized by cytochrome P450 (mainly CYP3A4). As these drugs are likely to be coadministered, these studies were performed to assess the pharmacokinetic interactions, safety and toleration of these drugs when taken together.

METHODS

Two randomized placebo-controlled studies were conducted in healthy male volunteers. Study A was an open parallel-group study of the effect of indinavir on the steady-state pharmacokinetics of voriconazole in 18 volunteers (nine subjects in each group). Subjects received voriconazole 200 mg twice daily (days 1-7), then voriconazole 200 mg twice daily + indinavir 800 mg or placebo three times daily (days 8-17). Study B was a double-blind, randomized, two-way crossover study of the effect of voriconazole on the steady-state pharmacokinetics of indinavir in 14 volunteers. They received indinavir 800 mg three times daily + voriconazole 200 mg or placebo twice daily for two 7-day treatment periods separated by a washout period of at least 7 days. Pharmacokinetic parameters were compared within treatment groups at days 7 and 17 in Study A and between treatment groups on day 7 of each period in Study B. All adverse events were recorded.

RESULTS

Study A: Seventeen subjects were evaluable for pharmacokinetic analysis (eight voriconazole + indinavir, nine voriconazole + placebo). The day 17/day 7 ratios for Cmax and AUCtau were estimated as 102%[90% confidence interval (CI) 91, 114] and 107% (90% CI 98, 118), respectively. Study B: Fourteen subjects were evaluable for pharmacokinetic analysis in each treatment period. The ratios between the geometric means for indinavir + voriconazole vs. indinavir + placebo were: Cmax, 91% (90% CI 83, 101), AUCtau, 87% (90% CI 77, 100), and Cmin, 101% (90% CI 82, 125). Trough plasma concentrations of indinavir were above the concentration required to inhibit HIV replication (IC95) in both treatment periods. Voriconazole coadministered with indinavir was well tolerated in both studies.

CONCLUSIONS

The coadministration of voriconazole and indinavir in healthy volunteers had no clinically significant effect on the pharmacokinetics of either voriconazole or indinavir.

Voriconazole potentiates warfarin-induced prothrombin time prolongation

AIMS

Voriconazole is a novel triazole with broad-spectrum antifungal activity. It is likely that some patients receiving voriconazole may also require treatment with the anticoagulant warfarin. Cytochrome P450 isoenzymes are important in the metabolism of both these drugs. This study investigated the effect of voriconazole on the pharmacodynamics of warfarin by measuring prothrombin time, and also evaluated the safety and tolerability of the coadministered drugs.

METHODS

This was a double-blind, placebo-controlled, two-way crossover study in which healthy male subjects received either 300 mg voriconazole or placebo twice daily on days 1-12, plus a single oral dose of 30 mg warfarin on day 7 of each study period. Volunteers were randomized to one of the following treatment sequences: voriconazole + warfarin followed by placebo + warfarin or placebo + warfarin followed by voriconazole + warfarin. There was a washout of at least of 7 days between treatment periods.

RESULTS

The mean Cmax, AUCtau and tmax for voriconazole were 3736 ng ml-1, 25 733 ng.h ml-1, and 1.66 h, respectively. Both the mean maximum change from baseline prothrombin time and the mean area under the effect curve (AUEC) for prothrombin time during coadministration with voriconazole (17 s and 3211 s.h, respectively) were statistically significantly greater than the mean values observed during the placebo period (8 s and 2282 s.h ). Prothrombin times were still increased by a mean value of 5.4 s 144 h post warfarin dose following coadministration with voriconazole compared with a mean value of 0.6 s in the placebo treatment period.

CONCLUSIONS

Coadministration of voriconazole and warfarin potentiates warfarin-induced prothrombin time prolongation. Regular monitoring of prothrombin time is recommended if these drugs are coadministered, with appropriate adjustment of the dose of warfarin.

Effect of food on the pharmacokinetics of multiple-dose oral voriconazole

AIMS

Voriconazole is a new triazole antifungal agent with activity against a range of clinically important and emerging pathogens. This study determined the effect of food on the pharmacokinetics of voriconazole in healthy volunteers.

METHODS

This was an open, randomized, two-way crossover, multiple-dose study in male volunteers. Twelve subjects received voriconazole 200 mg twice daily for 6.5 days. Each dose was administered either with food or in the fasted state, i.e. not within 2 h of food. Treatment periods were separated by a minimum 7-day washout period. Plasma samples were taken for the estimation of voriconazole plasma concentrations on days 1 and 7. Safety and toleration were assessed by monitoring of both laboratory safety tests and adverse events.

RESULTS

Administering voriconazole with food significantly decreased both day 7 AUCtau and Cmax by approximately 35% (9598-7520 ng.h ml-1; P = 0.003) and 22% (2038-1332 ng ml-1; P = 0.008), respectively. Administering voriconazole with food statistically significantly delayed absorption, evident from tmax values; the mean difference for tmax on day 7 was 1.1 h. The terminal phase rate constant was unchanged by administering voriconazole with food. The fasted terminal phase half-life was 7.3 h compared with 6.6 h for the fed state. Visual inspection of Cmin values suggests that steady state was achieved after 5 days in both dietary states. Voriconazole accumulation, as assessed by ratios of Cmax and AUCtau on days 1 and 7, was statistically significantly greater when administered with food (Cmax, P = 0.010, AUCtau, P = 0.006). Mean Cmax accumulation in the fasted state was 2.1-fold compared with 3.5-fold in the fed state. AUCtau accumulation in the fasted state was 3.1-fold compared with 4.2-fold in the fed state. There were no discontinuations due to adverse events or laboratory abnormalities. Treatment-related mild-to-moderate visual disturbances were experienced by six out of 12 subjects.

CONCLUSIONS

The bioavailability of twice-daily 200 mg voriconazole is reduced by approximately 22% as measured by AUCtau after multiple dosing when taken with food, compared with fasting.

Coadministration of voriconazole and phenytoin: pharmacokinetic interaction, safety, and toleration

AIMS

Voriconazole is a new triazole antifungal agent, and is metabolized by the cytochrome P450 isoenzymes CYP2C9, CYP2C19, and, to a lesser extent, by CYP3A4. Phenytoin is an inducer of CYP3A4 activity, and a substrate and inducer of CYP2C9 and CYP2C19. The present studies investigated the pharmacokinetic interactions of voriconazole and phenytoin when coadministered.

METHODS

Two placebo-controlled parallel-group studies were conducted in healthy male volunteers. Study A was an open-label study and investigated the effect of phenytoin (300 mg once daily) on the steady-state pharmacokinetics of voriconazole (200 mg and 400 mg twice daily). Study B was a double-blind randomized study to investigate the effects of voriconazole (400 mg twice daily) on the steady-state pharmacokinetics of phenytoin (300 mg once daily). Cmax and AUCtau were compared at days 7, 21, and 28 (Study A), and at days 7 and 17 (Study B). All adverse events were recorded.

RESULTS

Study A: 21 subjects were evaluable (10 voriconazole + phenytoin, 11 voriconazole + placebo). For subjects receiving voriconazole (200 mg twice daily) plus phenytoin, the day 21/day 7 ratios for voriconazole Cmax and AUCtau were 60.7%[90% confidence interval (CI) 50.1, 73.6] and 35.9% (90% CI 29.7, 43.3), respectively. Adjusted for voriconazole + placebo, the ratios between the means were 50.7% (90% CI 38.8, 66.1) and 30.6% (90% CI 23.5, 39.7), respectively. When the dose of voriconazole was increased to 400 mg twice daily, the day 28/day 7 ratios for voriconazole Cmax and AUCtau were 134% (90% CI 89.2, 200) and 139% (90% CI 97.3, 199), respectively. Study B: 15 subjects were evaluable for pharmacokinetic assessments (six phenytoin + voriconazole, nine phenytoin + placebo). The ratios between the means for phenytoin + voriconazole/phenytoin + placebo on day 17 vs. day 7 were: phenytoin Cmax 167% (90% CI 144, 193) and phenytoin AUCtau 181% (90% CI 156, 210). All treatments were well tolerated: most adverse events were mild/moderate and transient.

CONCLUSIONS

Repeat dose administration of phenytoin decreased the mean steady-state Cmax and AUCtau of voriconazole by approximately 50% and 70%, respectively. Increasing the dose of voriconazole from 200 mg to 400 mg b.d. compensated for this effect. Repeat dose administration of 400 mg b.d. voriconazole increased the mean steady-state Cmax and AUCtau of phenytoin by approximately 70% and 80%, respectively. It is therefore recommended that plasma phenytoin concentrations are monitored and the dose adjusted as appropriate when phenytoin is coadministered with voriconazole.