An LC-MS/MS Bioanalytical Assay for the Determination of Gilteritinib in Rat Plasma and Application to a Drug-Drug Interaction Study.

BACKGROUND: Gilteritinib, a novel, potent FLT3/AXL inhibitor, was recently approved in Japan and USA for the treatment of adult patients who have relapsed or refractory acute myeloid leukemia (AML) with a FLT3 mutation. PURPOSE AND METHODS: In this study, we aimed to develop and validate a sensitive and simple ultra performance liquid chromatography tandem mass spectrometry (UPLC-MS/MS) method for the quantification of gilteritinib in plasma and to investigate whether CYP3A4 inhibitors (fluconazole and itraconazole) could influence the pharmacokinetics of gilteritinib from a drug-drug interaction study in rats. Sample preparation was done by a simple protein crash with acetonitrile containing the internal standard (IS) pirfenidone, followed by UPLC-MS/MS quantification. RESULTS: The assay was successfully validated in a 1-500 ng/mL calibration range for gilteritinib, where the lower limit of quantification (LLOQ) was set at 1 ng/mL. The intra-day and inter-day precisions for gilteritinib were less than 10.6%, and the accuracies were in the range of -14.5% to 11.1%. Recovery and matrix effect of the analyte and IS were acceptable, and the analyte was stable during the assay and storage in plasma samples. The validated UPLC-MS/MS method was successfully applied to a drug-drug interaction study between gilteritinib and CYP3A4 inhibitors (fluconazole and itraconazole) in rats. Itraconazole significantly increased the exposure of gilteritinib, and affected the pharmacokinetics of gilteritinib in rats, not fluconazole. CONCLUSION: A further clinical study should be conducted to investigate the effect of itraconazole on the metabolism of gilteritinib in subjects.

Fluconazole levels in serum and cerebrospinal fluid according to daily dosage in patients with cryptococcosis and other fungal infections

ABSTRACT Fluconazole is extensively used for the treatment of candidiasis and cryptococcosis. Among other factors, successful treatment is related to appropriate fluconazole levels in blood and cerebrospinal fluid. In the present study, fluconazole levels were determined in 15 patients, 14 of whom had AIDS and 13 had neurocryptococcosis. The only selection criterion was treatment with fluconazole, which was performed with a generic or similar form of the drug. Fluconazole level was determined by high performance liquid chromatography and the susceptibility profile of Cryptococcus spp. isolated from the patients was assessed by broth microdilution. Blood and cerebrospinal fluid fluconazole levels were found to be related to the fluconazole daily dose, and exceeded the minimum inhibitory concentration of this antifungal for the Cryptococcus spp. isolates. A good correlation was observed between serum and cerebrospinal fluid drug concentration. In conclusion, treatment with non-original fluconazole under usual medical practice conditions results in appropriate blood and cerebrospinal fluid levels of the drug for inhibiting Cryptococcus spp. susceptible to this antifungal drug. The relatively common failures of neurocryptococcosis treatment appear not to be due to insufficient fluconazole levels in the cerebrospinal fluid, especially with the use of daily doses of 400-800 mg.

Clinical impact and management of fluconazole discontinuation on sirolimus levels in bone marrow transplant patients.

Sirolimus, an immunosuppressant, is indicated post-allogeneic stem cell transplant to reduce the risk of graft-versus-host-disease. Sirolimus is metabolized by cytochrome P450 3A4 and is a substrate of the P-glycoprotein (P-gp) drug efflux pump. Interactions with known inhibitors of the CYP3A4 enzyme and P-glycoprotein, such as fluconazole, are anticipated. Co-administration of fluconazole leads to an increase in sirolimus blood concentrations due to an inhibition of metabolism. The discontinuation of fluconazole will likely result in a decline in sirolimus blood concentrations, leaving patients at risk of graft-versus-host-disease. We report on three patients managed by the Hematology, Oncology Blood and Marrow Transplant Program at the Alberta Children's Hospital. The discontinuation of fluconazole showed a marked reduction in sirolimus trough levels, requiring >200% increase in sirolimus dose to achieve therapeutic levels.

Reliable and Easy-To-Use Liquid Chromatography-Tandem Mass Spectrometry Method for Simultaneous Analysis of Fluconazole, Isavuconazole, Itraconazole, Hydroxy-Itraconazole, Posaconazole, and Voriconazole in Human Plasma and Serum.

BACKGROUND: A fast and easy-to-use liquid chromatography-tandem mass spectrometry method for the determination and quantification of 6 triazoles [fluconazole (FLZ), isavuconazole (ISZ), itraconazole (ITZ), hydroxy-itraconazole (OH-ITZ), posaconazole (PSZ), and voriconazole (VRZ)] in human plasma and serum was developed and validated for therapeutic drug monitoring. METHODS: Sample preparation was based on protein precipitation with acetonitrile and subsequent centrifugation. Isotope-labeled analogues for each analyte were used as internal standards. Chromatographic separation was achieved using a 50 × 2.1 mm, 1.9 µm polar Hypersil Gold C18 column and mobile phase consisting of 0.1% formic acid/acetonitrile (45%/55%, vol/vol) at a flow rate of 340 µL/min. The triazoles were simultaneously detected using a triple-stage quadrupole mass spectrometer operated in selected reaction monitoring mode with positive heated electrospray ionization within a single runtime of t = 3.00 minutes. RESULTS: Linearity of all azole concentration ranges was verified by the Mandel test and demonstrated for all azoles. All calibration curves were linear and fitted using least squares regression with a weighting factor of the reciprocal concentration. Limits of detection (µg/L/L) were FLZ, 9.3; ISZ, 0.3; ITZ, 0.6; OH-ITZ, 8.6; PSZ, 3.4; and VRZ, 2.1. The lower limits of quantitation (µg/L/liter) were FLZ, 28.3; ISZ, 1.0; ITZ, 1.7; OH-ITZ, 26.2; PSZ, 10.3; and VRZ, 6.3. Intraday and interday precisions ranged from 0.6% to 6.6% for all azoles. Intraday and interday accuracies (%bias) of all analytes were within 10.5%. In addition, we report on a 29-year-old white woman (94 kg body weight) with a history of acute myeloid leukemia who underwent stem cell transplantation. Because of diagnosis of aspergillus pneumonia, antifungal pharmacotherapy was initiated with different application modes and dosages of ISZ, and plasma concentrations were monitored over a time period of 6 months. CONCLUSIONS: A precise and highly sensitive liquid chromatography-tandem mass spectrometry method was developed that enables quantification of triazoles in plasma and serum matrix across therapeutically relevant concentration ranges. It was successfully implemented in our therapeutic drug monitoring routine service and is suitable for routine monitoring of antifungal therapy and in severely ill patients.

Insufficient fluconazole exposure in pediatric cancer patients and the need for therapeutic drug monitoring in critically ill children.

BACKGROUND: Fluconazole is recommended as first-line treatment in invasive candidiasis in children and infants. Although timely achievement of adequate exposure of fluconazole improves outcome, therapeutic drug monitoring is currently not recommended. METHODS: We conducted a retrospective study of critically ill children treated with fluconazole from January 2007 to October 2013 and for whom fluconazole concentrations were available. We collected demographic, clinical, and treatment data through review of the medical records and determined the correlation of clinical variables with the fluconazole concentration. Additionally, we assessed the relation between the fluconazole concentration and the time to culture conversion in patients with proven invasive candidiasis. RESULTS: In total, 99 pediatric patients met the inclusion criteria. The fluconazole concentration was considered subtherapeutic in 40% of the patients. Multiple linear regression analysis showed a significant, independent, and positive association of the fluconazole trough concentration with the fluconazole dose (P <.001), weight (P = .009), and the serum urea concentration (P = .003), and a significant, independent, and negative association with age (P = .004) and cancer as an underlying condition (P = .003). A higher fluconazole concentration was associated with a shorter time to culture conversion (hazard ratio = 1.076 [95% confidence interval, 1.017-1.138]; P = .011). CONCLUSIONS: The fluconazole concentration is not sufficient in pediatric cancer patients with the currently recommended dose regimen, and a higher fluconazole dose is required to achieve adequate drug exposure. Therapeutic drug monitoring of fluconazole can be a valuable tool to detect possible underexposure in critically ill children.

Cryptococcus gattii osteomyelitis and compounded itraconazole treatment failure in a Pesquet's parrot (Psittrichas fulgidus).

A 14-yr-old female Pesquet's parrot (Psittrichas fulgidus) presented for lethargy and decreased ability to fly. Physical exam was unremarkable. Blood work showed an elevated white blood cell count and a strong positive Aspergillus galactomannan titer. Empirical Aspergillus treatment was initiated with compounded generic itraconazole. Radiographs revealed an irregular osteolytic lesion isolated to the distal right humerus. Bone biopsy of the lesion, cytology, and histopathology were diagnostic for osteomyelitis with intralesional yeasts confirmed to be Cryptococcus gattii on fungal culture. After 2 mo of compounded itraconazole treatment, the bird developed dyspnea and dysphagia due to new Cryptococcus lesions in the proximal trachea and glottis. Plasma itraconazole levels were measured and found to be undetectable; therefore, treatment was changed to fluconazole. Twenty-four months after initial presentation, clinical signs improved, but radiographic and histopathology lesions were static. Initial treatment failure was believed to be due to the use of compounded generic itraconazole, which lacks cyclodextrin, a carrier agent used to improve oral absorption, found in commercial itraconazole.

Pharmacokinetic drug interactions involving vortioxetine (Lu AA21004), a multimodal antidepressant.

BACKGROUND AND OBJECTIVE: The identification and quantification of potential drug-drug interactions is important for avoiding or minimizing the interaction-induced adverse events associated with specific drug combinations. Clinical studies in healthy subjects were performed to evaluate potential pharmacokinetic interactions between vortioxetine (Lu AA21004) and co-administered agents, including fluconazole (cytochrome P450 [CYP] 2C9, CYP2C19 and CYP3A inhibitor), ketoconazole (CYP3A and P-glycoprotein inhibitor), rifampicin (CYP inducer), bupropion (CYP2D6 inhibitor and CYP2B6 substrate), ethinyl estradiol/levonorgestrel (CYP3A substrates) and omeprazole (CYP2C19 substrate and inhibitor). METHODS: The ratio of central values of the test treatment to the reference treatment for relevant parameters (e.g., area under the plasma concentration-time curve [AUC] and maximum plasma concentration [C max]) was used to assess pharmacokinetic interactions. RESULTS: Co-administration of vortioxetine had no effect on the AUC or C max of ethinyl estradiol/levonorgestrel or 5'-hydroxyomeprazole, or the AUC of bupropion; the 90 % confidence intervals for these ratios of central values were within 80-125 %. Steady-state AUC and C max of vortioxetine increased when co-administered with bupropion (128 and 114 %, respectively), fluconazole (46 and 15 %, respectively) and ketoconazole (30 and 26 %, respectively), and decreased by 72 and 51 %, respectively, when vortioxetine was co-administered with rifampicin. Concomitant therapy was generally well tolerated; most adverse events were mild or moderate in intensity. CONCLUSION: Dosage adjustment may be required when vortioxetine is co-administered with bupropion or rifampicin.

Plasma concentrations of fluconazole after a single oral dose and administration in drinking water in cockatiels (Nymphicus hollandicus).

Candidiasis frequently affects the oropharynx, esophagus, and crop of juvenile birds with immature immune systems and adult birds that have received long-term antibiotic treatment. Fluconazole is used extensively in human medicine to treat mucosal and invasive candidiasis and has been used in birds; however, there have been few pharmacokinetic studies in avian species to guide safe and effective treatment. The purpose of the present study was to investigate the disposition of fluconazole in cockatiels (Nymphicus hollandicus) after single oral dose administration and to determine if therapeutic plasma concentrations could be safely achieved by providing medicated water. Twenty-eight cockatiels were placed into 7 groups and were orally administered a 10 mg/kg fluconazole suspension. Blood samples were collected from each group for plasma fluconazole assay at serial time points. Fluconazole-medicated drinking water was prepared daily and offered to 15 cockatiels at a concentration of 100 mg/L for 8 days. Blood was collected for plasma fluconazole assay at 2 time points on days 3 and 7. When using naive averaged data in the single-dose study, pharmacokinetic parameters were similar for both compartmental and noncompartmental analyses. The elimination half-life of fluconazole was 19.01 hours, maximum plasma concentration was 4.94 microg/mL, time until maximal concentration was 3.42 hours, and the area under the plasma concentration versus time curve (AUC) was 149.28 h x microg/mL. Computer-simulated trough and peak plasma concentrations at steady-state after multiple doses of fluconazole at 10 mg/kg every 24 hours, 10 mg/kg every 48 hours, and 5 mg/kg every 24 hours were approximately 4.1-8.5 microg/mL, 1.2-6.0 microg/mL, and 2.0-4.3 microg/mL, respectively. Mean +/- SD plasma fluconazole concentrations for the 100 mg/L medicated water study at 0800 and 1600 hours on day 3 were 3.69 +/- 1.22 microg/mL (range, 1.73-5.26 microg/mL) and 4.17 +/- 1.96 microg/mL (range, 3.58-7.49 microg/mL), respectively, and at 0800 and 1600 hours on day 7 were 4.78 +/- 0.91 microg/mL (range, 2.62-6.11 microg/mL) and 6.61 +/- 1.67 microg/mL (range, 3.76-8.78 microg/ mL), respectively. Treatment with fluconazole administered orally at a dosage of 5 mg/kg once daily or 10 mg/kg every 48 hours or fluconazole administered in the drinking water at a concentration of 100 mg/L is predicted to maintain plasma concentrations in most cockatiels that exceed the minimum inhibitory concentration of 90% or therapeutic AUC:MIC of most strains of Candida albicans (by using susceptibility data from humans). The compounded oral suspension was stable for 14 days when stored at 5 degrees C (41 degree sF) and protected from light.

Monitoring and impact of fluconazole serum and cerebrospinal fluid concentration in HIV-associated cryptococcal meningitis-infected patients.

OBJECTIVES: The aim of the present study was to assess fluconazole pharmacokinetic measures in serum and cerebrospinal fluid (CSF); and the correlation of these measures with clinical outcomes of invasive fungal infections. METHODS: A randomized trial was conducted in HIV-infected patients receiving three different regimens of fluconazole plus amphotericin B (AmB) for the treatment of cryptococcal meningitis. Regimens included fluconazole 400 mg/day+AmB (AmB+Fluc400) or fluconazole 800 mg/day+AmB (AmB+Fluc800) (14 days followed by fluconazole alone at the randomized dose for 56 days); or AmB alone for 14 days followed by fluconazole 400 mg/day for 56 days. Serum (at 24 h after dosing) and CSF samples were taken at baseline and days 14 and 70 (serum only) for fluconazole measurement, using gas-liquid chromatography. RESULTS: Sixty-four treated patients had fluconazole measurements: 11 in the AmB group, 12 in the AmB+Fluc400 group and 41 in the AmB+Fluc800 group. Day 14 serum concentration geometric means were 24.7 mg/L for AmB+Fluc400 and 37.0 mg/L for AmB+Fluc800. Correspondingly, CSF concentration geometric means were 25.1 mg/L and 32.7 mg/L. Day 14 Serum and CSF concentrations were highly correlated with AmB+Fluc800 (P<0.001, r=0.873) and AmB+Fluc400 (P=0.005, r=0.943). Increased serum area under the curve (AUC) appears to be associated with decreased mortality at day 70 (P=0.061, odds ratio=2.19) as well as with increased study composite endpoint success at days 42 and 70 (P=0.081, odds ratio=2.25 and 0.058, 2.89, respectively). CONCLUSION: High fluconazole dosage (800 mg/day) for the treatment of HIV-associated cryptococcal meningitis was associated with high serum and CSF fluconazole concentration. Overall, high serum and CSF concentration appear to be associated with increased survival and primary composite endpoint success.

Serum levels of fluconazole in patients after cytotoxic chemotherapy for hematological malignancy.

We performed a prospective evaluation of pharmacokinetics of fluconazole administered for prophylactic purposes to 19 patients after cytotoxic chemotherapy for hematological malignancies. On days 7 and 15, we obtained 5 ml of blood from each patient. If fluconazole was administered orally, blood samples were drawn 2, 8, and 24 hr after ingestion of the drug. If it was administered intravenously, blood samples were drawn 1, 8, and 24 hr post-injection. Serum fluconazole levels were analyzed by HPLC with ultraviolet light detection. In patients receiving 200 or 400 mg of fluconazole per day, maximal serum levels were 7.9 and 15.6 mg/l and minimum levels were 5.0 and 10.3 mg/l, respectively. There was no significant difference in serum fluconazole levels comparing the levels after oral and intravenous administration, and pharmacokinetic parameters of fluconazole were comparable at each time point within one dose level. However, considerable variation in serum fluconazole levels was noted in this study, as the maximal serum levels ranged from 4.0 to 13.3 mg/l and from 8.7 to 26.9 mg/l in patients receiving 200 and 400 mg of fluconazole orally, respectively. These variations may be associated with prophylactic failures for patients with insufficient fluconazole concentrations. Multiple regression analysis showed significant correlation between serum fluconazole levels and some variables including dose of fluconazole, age, serum aspartate aminotransferase levels and blood urea nitrogen levels. These variations may be associated with disturbance of body water balance, such as massive hemorrhage and dehydration.

Clinical pharmacokinetics of fluconazole in superficial and systemic mycoses.

The bis triazole agent fluconazole is used widely in the treatment of superficial and deep mycoses. A single oral dose of fluconazole 150 mg gives a mean long term clinical cure rate of 84 +/- 5% and is considered a valuable alternative to other topical antifungal drugs for vaginal candidiasis. A clinical cure rate of 90.4% for oropharyngeal candidiasis was obtained with 100mg daily for a minimum of 14 days; however, as for the other azoles the rate of relapse was large (40%) in immunocompromised patients. A daily dose of 100mg for at last 3 weeks gave satisfying outcomes for oesophageal candidiasis. Most patients (71 to 86%) with signs and symptoms of urinary tract candidiasis show beneficial clinical results when given oral fluconazole 50mg for several weeks. Fluconazole 50 to 150 mg given for weeks or months results in over 90% clinical cure or improvement for cutaneous mycosis including tinea, pityriasis, cryptococcosis and candidiasis. Prolonged (6 to 12 months) fluconazole 150 mg once a week is needed to treat onychomycosis successfully. Higher oral doses (200 to 400 mg daily) for long periods are generally used to treat deep mycoses such as meningitis, ophthalmitis, pneumonia, hepatosplenic mycosis and endocarditis. Fluconazole is effective for treating the fungal peritonitis which can complicate continuous ambulatory peritoneal dialysis (CAPD). A regimen of 50 mg intraperitoneally or 100 mg orally was used in these patients with impaired renal function. The dosage schedules used to treat disseminated fungal infections due to systemic mycoses with different or multiple foci of infections vary widely, with doses of 50 to 400 mg given orally or intravenously for between 1 week and several months. The most recent clinical reports have investigated the use of prophylaxis with fluconazole 100 to 400 mg daily, in immunocompromised patients. Fluconazole is found in body fluids such as vaginal secretions, breast milk, saliva, sputum and cerebrospinal fluid at concentrations comparable with those determined in blood after single or multiple doses. There is an excellent linear plasma concentration-dose relationship, but the mycological and clinical responses do not appear to be well correlated with the dose. A total maximum daily dose of 1600 mg is recommended to avoid neurological toxicity. Data from pharmacokinetic studies conducted in patients, mainly those with AIDS, and using a 1-compartment model give very constant parameters similar to those obtained in healthy individuals. Bioavailability, measured in HIV-positive patients and those with AIDS, exceeded 93% for tablets, suspension and suppositories. The time to reach peak plasma concentrations (tmax) was 2.4 to 3.7 hours. The peak plasma drug concentration (Cmax) obtained after a 100 mg oral dose was 2 mg/L. Areas under the concentration-time curve (AUC) obtained in different studies all correlate well with the dose (r = 0.926). The AUC determined after 200 and 25 mg suppositories were similarly well correlated. Hypochlorhydria does not affect the absorption of fluconazole, neither does food intake, race (Japanese or Caucasian) or gastrointestinal resection. Binding to plasma protein is low (11.14%) and is increased to 23% in cancer patients. Fluconazole is rapidly distributed to the tissue, where it accumulates. Tissues fall into 1 of 4 groups of increasing drug concentration: blood, bone and brain have the lowest concentrations, and spleen has the highest. The volume of distribution (Vd) remains stable at 46.3 +/- 7.9L and is considered to be an 'invariant' parameter across species. Fluconazole is poorly metabolised and is mainly eliminated unchanged in the urine. The percentage of the dose recovered in the urine in 48 hours is close to 60%. Concentrations in the urine are high and the half-life (t1/2) is long (37.2 +/- 5.5h) in patients, mainly those with AIDS, which is not significantly different from the t1/2 (31.4 +/- 4.7 hours) in healthy individuals. (ABSTRACT TRUN

Pharmacokinetics of oral fluconazole when used for prophylaxis in bone marrow transplant recipients.

The pharmacokinetics of fluconazole was investigated in 20 bone marrow transplant patients following oral administration of 200 mg of this drug. Blood samples were collected from each patient at different time intervals within 48 h after the first dose, and fluconazole was measured in plasma by high-performance liquid chromatography with UV detection. Urine was collected from 14 of these patients and analyzed similarly. The plasma concentration-time data exhibited the characteristics of the one-compartment model with first-order absorption quite well. The means +/- standard deviations of half-lives for absorption and elimination, peak concentration, time to peak, mean residence time, apparent volumes of distribution, area under the curve, and apparent oral clearance observed in these patients were 2.84 +/- 1.34 h, 19.94 +/- 18.7 h, 4.45 +/- 1.86 microg/ml, 8.34 +/- 5.97 h, 39.57 +/- 20.5 h, 0.874 +/- 0.48 liter/kg, 156.0 +/- 60.6 microg x h/ml, and 0.0256 +/- 0.0138 liter/h x kg, respectively. The amount of fluconazole excreted in urine in 24 h was 67.1 +/- 83 mg, which represents 33.55% +/- 41.6% of the dose administered. Patients who developed hemorrhagic cystitis excreted significantly (P < or = 0.0094) more fluconazole in 24 h than did those who did not.

Effect of repeated dosing on the pharmacokinetics of oral fluconazole in bone marrow transplant patients.

We examined the pharmacokinetics of fluconazole in 11 bone marrow transplant patients after multiple oral daily dose of 200 mg of this drug. Blood was sampled at different intervals on day 1, day 13, and day 27. No dose was given on day 2, day 14, and day 28 to allow the concentration-time data to be collected over 48 hours. The 24 hour urine was also collected, and fluconazole was analyzed in both plasma and urine by a high performance liquid chromatography. The plasma concentration-time data were best described by the one-compartment model with first-order absorption. The overall inter-day change and the difference between day 1 and day 27 in the rate constant for absorption (ka), peak plasma concentration (Cmax), through plasma concentration (Cmin), time-to-peak (tmax), area-under-the-curve 0-24 (AUC0-24), rate constant for elimination (ka), mean residence time after oral administration (MRTor), and fraction of the dose excreted unchanged in urine 24 hours (fu24) were significant (P < or = 0.0029 and P < or = 0.01, respectively). However, the difference between day 1 and day 13 was significant (P < or = 0.05) only in ka, tmax, Cmax, Cmin, and AUC0-24, and between day 13 and day 27 was significant (P < or = 0.05) only in ka, Cmin, ka, and MRTor. There was no significant inter-day change in the renal clearance. The significant (P < or = 0.05) increases in Cmax, Cmin, and AUC0-24 after the dose given on day 13 as compared with day 1, and in Cmin on day 27 as compared with day 13 indicate that, in contrast to volunteers, the steady state condition was not reached on day 13 and possibly not on day 27 in these patients. This perhaps should be taken into account when prescribing fluconazole to seriously ill patients.

Treatment of experimental cryptococcal meningitis with fluconazole: impact of dose and addition of flucytosine on mycologic and pathophysiologic outcome.

Fluconazole is effective in the therapy of cryptococcal meningitis in patients with AIDS. The optimal dosage of fluconazole and the impact of combination with flucytosine are not known. In this study, rabbits with experimental cryptococcal meningitis were given fluconazole at low, intermediate, or high dose or in combination with a low or intermediate dose of flucytosine. Serial cerebrospinal fluid (CSF) examinations showed that all three doses of fluconazole and low-dose fluconazole in combination with intermediate-dose flucytosine were effective in reducing CSF cryptococcal titer, lactate, white blood cell count, and cryptococcal antigen (CRAG) titers. The intermediate and high doses of fluconazole reduced CSF fungal (P < .05) and CRAG (P < .001) titers earlier than low-dose fluconazole alone or in combination with flucytosine. Only the highest dose of fluconazole reduced brain edema after 7 days. In this model of cryptococcal meningitis, there was evidence of a dose response with fluconazole but no in vivo synergism with flucytosine.

Inhibition of all-trans-retinoic acid metabolism by fluconazole in vitro and in patients with acute promyelocytic leukemia.

All-trans-retinoic acid induces acute promyelocytic leukemia cell differentiation in vitro, and it produces greater than 90% complete remissions in patients with acute promyelocytic leukemia. Despite the high response rate, the majority of patients relapse with continued trans-retinoic acid therapy, and disease progression has been observed to be accompanied by an increase in the metabolism of trans-retinoic acid in the patients. In this study, the pharmacokinetic disposition of trans-retinoic acid was determined by HPLC in patients with acute promyelocytic leukemia before and after concurrent therapy with the triazole antimycotic agent fluconazole. Treatment with trans-retinoic acid for 1 week reduced the area under the plasma trans-retinoic acid concentration vs time curve in one patient by 67%, from 277 to 91 ng/mL/hr. Trans-retinoic acid pharmacokinetics were repeated after the second dose of fluconazole, administered 1 hour prior to the retinoid, and the AUC was found to be 401 ng/mL/hr, a greater than 4-fold increase from the pre-fluconazole level. A similar, though more modest, effect of fluconazole was seen in a second acute promyelocytic leukemia patient. The effect of fluconazole on trans-retinoic acid metabolism was examined in vitro using isolated human hepatic microsomes. Fluconazole inhibited the NADPH-dependent cytochrome P450-mediated catabolism of trans-retinoic acid in a concentration-dependent manner. Although fluconazole was approximately one-half as potent an inhibitor when compared with ketoconazole, a related antifungal drug, 60-90% inhibition was observed at the concentrations of fluconazole measured in the acute promyelocytic leukemia patients. Neither fluconazole nor ketoconazole inhibited lipid hydroperoxide-mediated metabolism of trans-retinoic acid. Since fluconazole is a well-tolerated agent frequently administered to leukemia patients, its use in combination with trans-retinoic acid merits further consideration.

Safety, plasma concentrations, and efficacy of high-dose fluconazole in invasive mold infections.

A trial of the antifungal triazole fluconazole was conducted in cancer patients with presumed or proven mold infection. Groups of patients received fluconazole at four dosages (800, 1200, 1600, or 2000 mg/day). Adverse events, plasma levels, and clinical response were examined. Thirty-nine patients were enrolled. The 28 evaluable patients had presumed (13 patients) or proven (15) mold infection with Aspergillus (4) and Fusarium (3) species, Zygomycetes organisms (1), or nonspeciated mold (7). Adverse effects included elevated liver function test results (8 patients), nausea and vomiting (2), and erythema multiforme (1). Neurologic toxicity occurred in 3 patients receiving 2000 mg/day. Average steady-state peak plasma concentrations were 51.8, 74.4, and 91.8 mg/L for dosages 1200, 1600, and 2000 mg/day, respectively. Seven of 28 evaluable patients responded. Response did not appear to be related to dose. Fluconazole is well tolerated at total daily doses up to 1600 mg. The data suggest a linear plasma concentration-dose relationship. The activity of fluconazole in refractory mold infections seems to be limited.

Protein binding of itraconazole and fluconazole in patients with cancer.

The serum protein binding of itraconazole and fluconazole, new azole antifungal agents, has been investigated in vitro, in serum from healthy volunteers and from patients with cancer. Protein binding was determined by ultrafiltration. Concentrations of both alpha 1-acid glycoprotein (AAG) and albumin (HSA) were measured in all serum samples. The serum protein binding of itraconazole was reduced in patients (96.02 +/- 1.41% vs 97.25 +/- 0.54%; p < 0.01) with respect to healthy volunteers. In contrast, fluconazole protein binding was increased in the same group of patients (22.96 +/- 3.60% vs 13.30 +/- 2.58%; p < 0.01). HSA levels in cancer patients were significantly decreased (p < 0.01) and AAG levels were found to be significantly elevated in patients with respect to control subjects (p < 0.05). A significant linear relationship between the bound/unbound concentration ratio of itraconazole and HSA (r2 = 0.3340; p < 0.01) was found. Similarly, a significant relation was established between the bound/unbound concentration ratio of fluconazole and AAG levels (r2 = 0.2235; p < 0.05). Thus, a weak association between the binding of these drugs and serum protein levels has been observed. It is concluded that both antifungal drugs show different protein binding behaviour in cancer patients.

Efficacy and safety of fluconazole prophylaxis for fungal infections after marrow transplantation--a prospective, randomized, double-blind study.

A randomized, double-blind, placebo-controlled trial assessed the efficacy and toxicity of 400 mg/day fluconazole in preventing fungal infections during the first 75 days after marrow transplantation. During prophylaxis, systemic fungal infections occurred in 10 (7%) of 152 fluconazole-treated patients compared with 26 (18%) of 148 placebo-treated patients (P = .004). There were no Candida albicans infections in fluconazole recipients compared with 18 in placebo recipients (P < .001) and no significant increase in Candida infections other than C. albicans. Fluconazole also significantly reduced the incidence of superficial fungal infections (P < .001), fungal colonization (P = .037), and empiric amphotericin B use (P = .005). The probability of survival was improved in fluconazole recipients, in whom 31 deaths occurred up to day 110 after transplantation compared with 52 deaths in placebo recipients (P = .004). No clinically significant toxicity was detected with fluconazole use. Prophylactic fluconazole was safe and significantly reduced systemic fungal infections with other benefits, including improved survival at day 110 after marrow transplantation.