Influence of alitretinoin on the pharmacokinetics of the oral contraceptive ethinyl estradiol/norgestimate.

BACKGROUND: Alitretinoin (9-cis retinoic acid) is currently registered in many European countries and in Canada as the only licensed treatment for severe chronic hand eczema unresponsive to potent topical corticosteroids. Alitretinoin, like all retinoids, is teratogenic, and women of child-bearing potential must strictly adhere to pregnancy-prevention measures. AIM: To investigate the influence of alitretinoin on the pharmacokinetics (PK) of ethinyl estradiol/norgestimate (Ortho Tri-Cyclen 28(®)), a commonly prescribed combination oral contraceptive. METHODS: In total, 16 healthy premenopausal women received three consecutive cycles of the triphasic contraceptive ethinyl estradiol/norgestimate together with concomitant oral alitretinoin 40 mg once daily during cycle 2. Steady-state PK (noncompartmental analysis) of ethinyl estradiol, 17-deacetyl norgestimate, alitretinoin and its main metabolite 4-oxo-alitretinoin were assessed alone and in combination. RESULTS: The PK profiles of ethinyl estradiol and 17-deacetyl norgestimate were similar when contraceptives were given alone or with alitretinoin, and the area under the plasma concentration vs. time curve and the maximum concentration met the conventional criteria for PK equivalence. Similarly, the influence of ethinyl estradiol/norgestimate on systemic exposure to alitretinoin and 4-oxo-alitretinoin was not clinically relevant. Alitretinoin was well tolerated when given either alone or with ethinyl estradiol/norgestimate. CONCLUSIONS: There was no clinically relevant influence of alitretinoin on the PK of ethinyl estradiol/norgestimate, and no influence of ethinyl estradiol/norgestimate on systemic exposure to alitretinoin and 4-oxo-alitretinoin. Consequently, oral contraception with ethinyl estradiol/norgestimate is an appropriate primary method of birth control during alitretinoin treatment for women of childbearing potential.

Low levels of alitretinoin in seminal fluids after repeated oral doses in healthy men.

BACKGROUND: Alitretinoin, like all retinoids, is teratogenic, and can only be given to women of childbearing potential if pregnancy is excluded and a strict contraceptive programme is followed. AIM: This study was designed to determine whether alitretinoin in the semen of men treated with alitretinoin poses a teratogenic risk to their female partners. METHODS: In total, 24 healthy men aged 18-45 years received alitretinoin 20 mg (n = 12) or 40 mg (n = 12), once daily for 14 days. Subjects in the 40 mg dose group provided ejaculate at baseline, on day 1, before and approximately 4 h after dosing on day 2, and at follow-up on study day 21 (± 2). RESULTS: Alitretinoin and 4-oxo-alitretinoin were detected in 11 of the 12 semen samples. The highest level of alitretinoin in semen was 7.92 ng/mL. Assuming an ejaculate volume of 10 mL, the amount of drug transferred in semen would be about 80 ng, 1/375,000 of a single 30 mg capsule. Complete absorption of 80 ng of alitretinoin from semen, presuming a volume of distribution confined to 5 L of circulating blood in the partner, would lead to an increase in plasma alitretinoin concentration of 0.016 ng/mL, which appears to be negligible compared with measured endogenous plasma levels. Increases in plasma levels of related retinoids are also negligible. CONCLUSIONS: Alitretinoin in the semen of men receiving up to 40 mg of oral alitretinoin per day is unlikely to be associated with teratogenic risk in their female partners. Barrier contraception is therefore not required for men taking alitretinoin.

Clinical pharmacokinetics of capecitabine.

Capecitabine is a novel oral fluoropyrimidine carbamate that is preferentially converted to the cytotoxic moiety fluorouracil (5-fluorouracil; 5-FU) in target tumour tissue through a series of 3 metabolic steps. After oral administration of 1250 mg/m2, capecitabine is rapidly and extensively absorbed from the gastrointestinal tract [with a time to reach peak concentration (tmax) of 2 hours and peak plasma drug concentration (Cmax) of 3 to 4 mg/L] and has a relatively short elimination half-life (t(1/2)) [0.55 to 0.89 h]. Recovery of drug-related material in urine and faeces is nearly 100%. Plasma concentrations of the cytotoxic moiety fluorouracil are very low [with a Cmax of 0.22 to 0.31 mg/L and area under the concentration-time curve (AUC) of 0.461 to 0.698 mg x h/L]. The apparent t(1/2) of fluorouracil after capecitabine administration is similar to that of the parent compound. Comparison of fluorouracil concentrations in primary colorectal tumour and adjacent healthy tissues after capecitabine administration demonstrates that capecitabine is preferentially activated to fluorouracil in colorectal tumour, with the average concentration of fluorouracil being 3.2-fold higher than in adjacent healthy tissue (p = 0.002). This tissue concentration differential does not hold for liver metastasis, although concentrations of fluorouracil in liver metastases are sufficient for antitumour activity to occur. The tumour-preferential activation of capecitabine to fluorouracil is explained by tissue differences in the activity of cytidine deaminase and thymidine phosphorylase, key enzymes in the conversion process. As with other cytotoxic drugs, the interpatient variability of the pharmacokinetic parameters of capecitabine and its metabolites, 5'-deoxy-5-fluorocytidine and fluorouracil, is high (27 to 89%) and is likely to be primarily due to variability in the activity of the enzymes involved in capecitabine metabolism. Capecitabine and the fluorouracil precursors 5'-deoxy-5-fluorocytidine and 5'-deoxy-5-fluorouridine do not accumulate significantly in plasma after repeated administration. Plasma concentrations of fluorouracil increase by 10 to 60% during long term administration, but this time-dependency is assumed to be not clinically relevant. A potential drug interaction of capecitabine with warfarin has been observed. There is no evidence of pharmacokinetic interactions between capecitabine and leucovorin, docetaxel or paclitaxel.

Preferential activation of capecitabine in tumor following oral administration to colorectal cancer patients.

PURPOSE: [corrected] Capecitabine (Xeloda) is a novel fluoropyrimidine carbamate rationally designed to generate 5-fluorouracil (5-FU) preferentially in tumors. The purpose of this study was to demonstrate the preferential activation of capecitabine, after oral administration, in tumor in colorectal cancer patients, by the comparison of 5-FU concentrations in tumor tissues, healthy tissues and plasma. METHODS: Nineteen patients requiring surgical resection of primary tumor and/or liver metastases received 1,255 mg/m2 of capecitabine twice daily p.o. for 5-7 days prior to surgery. On the day of surgery, samples of tumor tissue, adjacent healthy tissue and blood samples were collected simultaneously from each patient, 2 to 12 h after the last dose of capecitabine had been administered. Concentrations of 5-FU in various tissues and plasma were determined by HPLC. The activities of the enzymes (CD, TP and DPD) involved in the formation and catabolism of 5-FU were measured in tissue homogenates, by catabolic assays. RESULTS: The ratio of 5-FU concentrations in tumor to adjacent healthy tissue (T/H) was used as the primary marker for the preferential activation of capecitabine in tumor. In primary colorectal tumors, the concentration of 5-FU was on average 3.2 times higher than in adjacent healthy tissue (P = 0.002). The mean liver metastasis/healthy tissue 5-FU concentration ratio was 1.4 (P = 0.49, not statistically different). The mean tissue/plasma 5-FU concentration ratios exceeded 20 for colorectal tumor and ranged from 8 to 10 for other tissues. CONCLUSIONS: The results demonstrated the preferential activation of capecitabine to 5-FU in colorectal tumor, after oral administration to patients. This is explained to a great extent by the activity of TP in colorectal tumor tissue, (the enzyme responsible for the conversion of 5'-DFUR to 5-FU), which is approximately four times that in adjacent healthy tissue. In the liver, TP activity is approximately equal in metastatic and healthy tissue, which explains the lack of preferential activation of capecitabine in these tissues.

Bioequivalence of two tablet formulations of capecitabine and exploration of age, gender, body surface area, and creatinine clearance as factors influencing systemic exposure in cancer patients.

PURPOSE: The objective of the study was to assess the bioequivalence of two tablet formulations of capecitabine and to explore the effect of age, gender, body surface area and creatinine clearance on the systemic exposure to capecitabine and its metabolites. METHODS: The study was designed as an open, randomized two-way crossover trial. A single oral dose of 2000 mg capecitabine was administered on two separate days to 25 patients with solid tumors. On one day, the patients received four 500-mg tablets of formulation B (test formulation) and on the other day, four 500-mg tablets of formulation A (reference formulation). The washout period between the two administrations was between 2 and 8 days. After each administration, serial blood and urine samples were collected for up to 12 and 24 h, respectively. Unchanged capecitabine and its metabolites were determined in plasma using LC/MS-MS and in urine by NMRS. RESULTS: Based on the primary pharmacokinetic parameter, AUC(0-infinity) of 5'-DFUR, equivalence was concluded for the two formulations, since the 90% confidence interval of the estimate of formulation B relative to formulation A of 97% to 107% was within the acceptance region 80% to 125%. There was no clinically significant difference between the t(max) for the two formulations (median 2.1 versus 2.0 h). The estimate for C(max) was 111% for formulation B compared to formulation A and the 90% confidence interval of 95% to 136% was within the reference region 70% to 143%. Overall, these results suggest no relevant difference between the two formulations regarding the extent to which 5'-DFUR reached the systemic circulation and the rate at which 5'-DFUR appeared in the systemic circulation. The overall urinary excretions were 86.0% and 86.5% of the dose, respectively, and the proportion recovered as each metabolite was similar for the two formulations. The majority of the dose was excreted as FBAL (61.5% and 60.3%), all other chemical species making a minor contribution. Univariate and multivariate regression analysis to explore the influence of age, gender, body surface area and creatinine clearance on the log-transformed pharmacokinetic parameters AUC(0-infinity) and C(max) of capecitabine and its metabolites revealed no clinically significant effects. The only statistically significant results were obtained for AUC(0-infinity) and C(max) of intact drug and for C(max) of FBAL, which were higher in females than in males. CONCLUSION: The bioavailability of 5'-DFUR in the systemic circulation was practically identical after administration of the two tablet formulations. Therefore, the two formulations can be regarded as bioequivalent. The variables investigated (age, gender, body surface area, and creatinine clearance) had no clinically significant effect on the pharmacokinetics of capecitabine or its metabolites.

Effect of hepatic dysfunction due to liver metastases on the pharmacokinetics of capecitabine and its metabolites.

Capecitabine (Xeloda) is a rationally designed oral, tumor-selective fluoropyrimidine carbamate aimed at preferential conversion to 5-fluorouracil (5-FU) within the tumor. Because capecitabine is extensively metabolized by the liver, it is important to establish whether liver dysfunction altered the pharmacokinetics of capecitabine and its metabolites. This was investigated in 14 cancer patients with normal liver function and in 13 with mild to moderate disturbance of liver biochemistry due to liver metastases. They received a single oral dose of capecitabine (1255 mg capecitabine/m2) with serial blood and urine samples collected up to 72 h after administration. Concentrations of capecitabine and its metabolites were determined in plasma by high-performance liquid chromatography or liquid chromatography coupled to mass spectrometry and in urine by 19F-nuclear magnetic resonance spectroscopy. Although plasma concentrations of capecitabine, 5'-deoxy-5-fluorouridine, 5-FU, dihydro-5-FU, and alpha-fluoro-beta-alanine were, in general, higher in patients with liver dysfunction, the opposite was found for 5'-deoxy-5-fluorocytidine. These effects were not clinically significant. Total urinary recovery of capecitabine and its metabolites was 71% of the administered dose in patients with normal hepatic function and 77% in patients with hepatic impairment. The absolute bioavailability of 5'-deoxy-5-fluorouridine was estimated as 42% in patients with normal hepatic function and 62% in patients with impaired hepatic function. In summary, mild to moderate hepatic dysfunction had no clinically significant influence on the pharmacokinetic parameters of capecitabine and its metabolites. Although caution should be exercised when capecitabine is administered to patients with mildly to moderately impaired hepatic function, there is no need for, a priori, adjustment of the dose.

Influence of the antacid Maalox on the pharmacokinetics of capecitabine in cancer patients.

PURPOSE: In the present study the possible influence of the antacid Maalox on the pharmacokinetics of capecitabine (Xeloda) and its metabolites was investigated in cancer patients. METHODS: A total of 12 patients with solid, predominantly metastatic tumors of various origin received a single oral dose of 1250 mg/m2 of capecitabine (treatment A), a single oral dose of 1250 mg/m2 of capecitabine followed immediately by 20 ml of Maalox (treatment B), and a single oral dose of 1250 mg/m2 of capecitabine followed 2 h later by 20 ml of Maalox (treatment C) in an open, randomized, three-way cross over fashion. Serial blood and urine samples were collected for up to 24 h after each administration. Unchanged capecitabine and its metabolites were analyzed in plasma using liquid chromatography/mass spectrometry and in urine using nuclear magnetic resonance spectroscopy. RESULTS: Administration of Maalox either concomitantly with capecitabine or delayed by 2 h did not influence the time to peak plasma concentrations (Cmax) or the elimination half-lives of capecitabine and its metabolites. Unexpectedly, moderate increases in the Cmax and AUC0-infinity values obtained for capecitabine and 5'-deoxy-5-fluorocytidine were observed when Maalox was given together with capecitabine. However, these increases, which ranged between 10% and 31%, were not statistically significant (P > 0.05) and are not of clinical significance. There was no indication of consistent changes in the plasma concentrations of the other metabolites 5'-deoxy-5'-fluorouridine (5'-DFUR), 5-fluorouracil, and alpha-fluoro-beta-alanine. The Cmax and AUC0-infinity values recorded for these three metabolites increased and decreased in a stochastic manner. The magnitude of these changes was low (<13%) and not statistically significant. The primary statistical analysis of the AUC0-infinity obtained for 5'-DFUR provided a P value of 0.4524 and clearly indicated no significant difference between the treatments. The addition of Maalox had no influence on the overall urinary recovery or the proportion of the dose recovered as capecitabine or its metabolites from urine. CONCLUSION: At the dose used in this study, the effect of concomitantly delivered Maalox on the extent and rate of gastrointestinal absorption of capecitabine is not clinically significant. Therefore, there is no need to adjust the dose or timing of capecitabine administration in patients treated with Maalox.

Lack of bioequivalence of a generic mefloquine tablet with the standard product.

OBJECTIVE: To assess the bioequivalence between a generic tablet of mefloquine (Mephaquin = M1) with the reference tablet (Lariam = M2) in healthy volunteers. METHODS: This open label, randomized two-way crossover study was performed in a single centre. Following an overnight fast, eighteen healthy volunteers received a single oral dose of 750 mg mefloquine either in the form of three M1 lactabs or three M2 tablets. Serial blood samples were collected up to 8 weeks after drug administration. Plasma samples were analysed for mefloquine and its carboxylic acid metabolite using liquid chromatography and subsequent tandem mass spectrometry (LC-MS/MS). The pharmacokinetic parameters of mefloquine and its metabolite were estimated by non-compartmental methods. RESULTS: The pharmacokinetics of mefloquine after administration of M1 and M2 tablets were significantly different as reflected by the respective mean values of maximum plasma concentration (Cmax 656 vs 1018 ng x ml(-1)), time to reach maximum concentration (tmax 46 vs 13 h) and area under the plasma concentration-time curve (AUC0-->infinity 338 vs 432 microg x h x ml(-1)). No significant differences existed between the elimination half-lives of the two formulations (394 vs 396 h). The relative bioavailability (M1 vs M2) was 0.78 and ranged from 0.38 to 1.37. Bioequivalence could not be demonstrated for log-transformed data of AUC0-->infinity or AUC0-->last within a predefined range of 80-125% and for Cmax within a range of 70-143%. CONCLUSIONS: The observed differences in Cmax, tmax and AUC are consistent with a slower rate and lower extent of mefloquine absorption after administration of M1. Statistical evaluation of these kinetic data showed that the M1 tablet is not bioequivalent to the M2 tablet. Clinical consequences of this finding cannot be excluded.

Pharmacokinetics and safety of candesartan cilexetil in subjects with normal and impaired liver function.

OBJECTIVE: The influence of liver disease on the pharmacokinetics of candesartan, a long-acting selective AT1 subtype angiotensin II receptor antagonist was studied. METHODS: Twelve healthy subjects and 12 patients with mild to moderate liver impairment received a single oral dose of 12 mg of candesartan cilexetil on day 1 and once-daily doses of 12 mg on days 3-7. The drug was taken before breakfast. Serial blood samples were collected for 48 h after the first and last administration on days 1 and 7. Serum was analyzed for unchanged candesartan by HPLC with UV detection. RESULTS: The pharmacokinetic parameters on days 1 and 7 revealed no statistically significant influence of liver impairment on the pharmacokinetics of candesartan. Following single dose administration on day 1, the mean Cmax was 95.2 ng.ml-1 in healthy subjects and 109 ng.ml-1 in the patients. The AUC0-infinity was 909 ng.h.ml-1 in healthy volunteers and 1107 ng.h.ml-1 in patients and the elimination half-life was 9.3 h in healthy volunteers and 12 h in the patients. At steady state on day 7, mean Cmax values were similar in both groups (112 vs 116 ng.ml-1); the AUC tau was 880 ng.h.ml-1 in healthy subjects and 1080 ng.h.ml-1 in patients while the elimination half-life was 10 h in healthy subjects and 12 h in the patients with liver impairment. The ACU0-infinity on day 1 was almost identical to the AUC tau on day 7. A moderate drug accumulation of 20%, which does not require a dose adjustment, was observed following once-daily dosing in both groups. No serious or severe adverse events were reported. CONCLUSION: Mild to moderate liver impairment has no clinically relevant effect on candesartan pharmacokinetics, and no dose adjustment is required for such patients.

Pharmacokinetics and pharmacodynamics of mibefradil in hypertensive patients with varying degrees of renal insufficiency.

Mibefradil, the first member of the tetralol derivatives, a new class of calcium antagonists, is used for the treatment of hypertension and angina pectoris. This study was designed to investigate the effect of varying degrees of chronic renal impairment on mibefradil pharmacokinetics and pharmacodynamics. Neither pharmacokinetic nor pharmacodynamic parameters varied as a function of renal status. Additionally, hemodialysis removed only a relatively small fraction of drug from the body. It was concluded that the majority of renal-failure patients will not require a change in mibefradil dosage relative to patients with normal renal function. Following hemodialysis, supplemental mibefradil treatment should not be necessary.

Effect of food on the pharmacokinetics of capecitabine and its metabolites following oral administration in cancer patients.

Capecitabine (Ro 09-1978) is a novel oral fluoropyrimidine carbamate that was rationally designed to generate 5-fluorouracil (5-FU) selectively in tumors. The effect of food on the pharmacokinetics of capecitabine and its metabolites was investigated in 11 patients with advanced colorectal cancer using a two-way cross-over design with randomized sequence. Patients received repeated doses of 666 or 1255 mg/m2 of capecitabine twice daily. On study days 1 and 8, drug was administered following an overnight fast or within 30 min after consumption of a standard breakfast, and serial blood samples were collected. Concentrations of capecitabine and its metabolites [5'-deoxy-5-fluorocytidine (5'-DFCR), 5'-deoxy-5-fluorouridine (5'-DFUR), 5-FU, dihydro-5-fluorouracil (FUH2), and alpha-fluoro-beta-alanine (FBAL)] in plasma were determined by high-performance liquid chromatography or liquid chromatography/mass spectroscopy. Intake of food prior to the administration of capecitabine resulted in pharmacokinetic changes of all compounds involved. The extent of these changes, however, varied considerably between the various compounds. Maximum plasma concentration (Cmax) and area under the plasma concentration-time curve (AUC) values were decreased after food, and time until the occurrence of Cmax values were increased. In contrast, the apparent elimination half-life was not affected by food intake. The extent of change in Cmax and AUC was highest for capecitabine and decreased with the order of formation of the metabolites. The "before:after food" ratios of the Cmax values were 2.47 for capecitabine, 1.81 for 5'-DFCR, 1.53 for 5'-DFUR, 1.58 for 5-FU, 1.26 for FUH2, and 1.11 for FBAL. The before: after food ratios of the AUC values were 1.51 for capecitabine, 1.26 for 5'-DFCR, 1.15 for 5'-DFUR, 1.13 for 5-FU, 1.07 for FUH2, and 1.04 for FBAL. The results show that food has a profound effect on the AUC of capecitabine, a moderate effect on the AUC of 5'-DFCR, and only a minor influence on the AUC of the other metabolites in plasma. In addition, a profound influence on Cmax of capecitabine and most of its metabolites was found. Detailed information on the relationship between concentration and safety/efficacy is necessary to evaluate the clinical significance of these pharmacokinetic findings. At present, it is recommended that capecitabine be administered with food as this procedure was used in the clinical trials.

Tolerability and pharmacokinetics of Ro 42-1611 (arteflene) in man.

The safety, tolerability and pharmacokinetics of the antimalarial arteflene (Ro 42-1611) were evaluated in a single ascending dose, double-blind, placebo-controlled trial in healthy male volunteers. Six groups of 9 volunteers (6 active and 3 placebo) received single oral doses of 100, 300, 900, 1800, 2700 and 3600 mg as a drinking suspension in the fasted state. For pharmacokinetic evaluation serial plasma and urine samples were collected up to 48 h after drug intake. Samples were analyzed for unchanged drug and the 8-hydroxy-metabolite using a new HPLC assay with UV detection. Serial blood samples were also taken for pharmacodynamics (ex vivo inhibition of Plasmodium falciparum growth). No serious adverse events were reported and no withdrawals occurred. Laboratory parameters (haematology, blood chemistry, urinalysis), vital signs (blood pressure, heart rate, body temperature) and electrocardiograms revealed no clinically relevant changes. Highly significant inhibition of P. falciparum growth was observed in sera from subjects who received 300 mg or higher doses as early as 30 minutes and up to 8 h post dosing. Evaluation of the pharmacokinetics from the plasma concentration-time data showed that the mean Cmax and AUC values increased linearly with dose up to a dose level of 1800 mg. At higher doses a plateau was reached pointing to a saturation of absorption from the gastrointestinal tract. Maximum concentrations in plasma were reached 1.7 to 3.3 hours post-dose. The elimination half-lives were relatively short and ranged between 2 and 4 hours. In plasma, the 8-hydroxy-metabolite reached approximately 3 times the Cmax values of the unchanged substance.(ABSTRACT TRUNCATED AT 250 WORDS)

Single-dose pharmacokinetics of oral fleroxacin in bacteremic patients.

Fleroxacin is a new broad-spectrum quinolone which can be given by the oral route. The present study was designed to assess the influence of bacteremia on the pharmacokinetics of a single oral dose of fleroxacin. Thirteen patients with proven bacteremia (one or more pairs of positive blood cultures, no hypotension) were given a single 400-mg fleroxacin dose orally on two occasions while also receiving standard antibiotic therapy. The first dose was administered 12 to 36 h after the last positive blood culture was drawn (day 1), and a second dose was administered 7 days later (day 7 +/- 2) to compare the pharmacokinetics between the acute and the convalescent phases of the disease. Following each administration of fleroxacin, serial plasma samples were collected for up to 72 h and were analyzed for unchanged drug by a reversed phase high-pressure liquid chromatography technique. There were no significant changes in the following pharmacokinetic parameters (mean standard deviation) the maximum concentration of drug in serum (6.4 +/- 1.5 versus 6.7 +/- 1.9 mg/liter), the minimum concentration of drug in serum, defined as the concentration of drug in serum at 24 h postdose (3.0 +/- 1.7 versus 2.5 +/- 1.2 mg/liter), the time to the maximum concentration of drug in serum (2.3 +/- 1.4 versus 2.0 +/- 1.2 h), and the elimination half-life (19.7 +/- 8.0 versus 17.9 +/- 6.9 h). Fleroxacin clearances were compared for each individual patient. A positive correlation (R2 = 0.787) was found between the values measured on day 1 and day 7. Oral clearance of fleroxacin (CL = CL/F, where F is bioavailability was slightly, but not significantly, reduced during the bacteremic phase (oral clearance, 43.8+/- 23.5 versus 48.5 +/- 17.5 ml/min.). When compared with previous results obtained in healthy young subjects, longer times to the maximum concentration of drug in serum and elimination half-lives and higher areas under the curve were observed. This could be due to the bacteremic state, the old age of the patients (mean, 66 years), and the low renal clearance (mean calculated creatinine clearance, 71.1 ml/min). A single oral dose of 400 mg of fleroxacin provides sufficient levels in serum to cover susceptible microorganisms for at least 24 h in bacteremic patients. Renal function appeared to be the key element that had to be taken into consideration to adapt fleroxacin dosage profiles in our patient population. Bacteremia itself appeared to amplify that phenomenon, but to a much lesser extent than renal function did.

Pharmacokinetics of brodimoprim.

Brodimoprim is a dihydrofolate reductase inhibitor which is highly active against a broad spectrum of gram-negative and gram-positive bacteria. Single dose pharmacokinetics and dose proportionality of this drug were studied in healthy volunteers who received orally 150, 400 and 600 mg. Multiple dose pharmacokinetics were evaluated after administration of an oral loading dose of 400 mg followed by daily maintenance doses (tau = 24 h) of 200 mg on seven consecutive days. Plasma and urine samples were collected up to 4 days after dosing and analyzed for unchanged drug by an HPLC-assay with fluorescence detection. Approximately 4 hours after single oral administration of 150, 400 and 600 mg, Cmax-values of 1.5, 3.3 and 6.2 mg/l were observed. The corresponding AUC-values after these doses were 73, 156 and 290 mg.h/l, respectively, and reflect a good dose proportionality in the investigated range. In the postdistributive phase an elimination half-life of 32-35 h was determined which justifies once-daily administration. Total plasma clearance (Cls/F) reached approximately 40 ml/min and renal clearance was approximately 3 ml/min. Approximately 80% of the dose was recovered from urine, but only 4-7% could be identified as unchanged drug. With faeces less than 10% of the dose was excreted predominantly as parent drug. Hence, metabolic degradation is the dominant elimination process of brodimoprim. The apparent volume of distribution (V beta/F) was high (approximately 1.5 l/kg) and reflects the good penetration of brodimoprim into most body fluids and tissues. During multiple dosing, the pharmacokinetic parameters of brodimoprim remained unchanged, and induction or inhibition of the drug metabolizing/eliminating enzymes can be excluded.(ABSTRACT TRUNCATED AT 250 WORDS)

Influence of rifampin on fleroxacin pharmacokinetics.

Staphylococcus aureus infections have been successfully treated in animal models with the combination of fleroxacin and rifampin. We studied the influence of rifampin, a potent cytochrome P-450 inducer, on the pharmacokinetics and biotransformation of fleroxacin in 14 healthy young male volunteers. Subjects were given 400 mg of fleroxacin orally once a day for 3 days to reach steady state. After a wash-out period of 2 days, the same subjects received 600 mg of rifampin orally once daily for 7 days. On days 5 to 7 of rifampin treatment, 400 mg of fleroxacin was again administered once daily. Concentrations of fleroxacin as well as its two major urinary metabolites, N-demethyl- and N-oxide-fleroxacin, in plasma and urine were determined by reverse-phase high-performance liquid chromatography. The extent of hepatic enzyme induction by rifampin was confirmed by a significant increase of 6-beta-hydroxycortisol urinary output from 160.8 +/- 41.4 to 544.8 +/- 120.7 micrograms/4 h. There were no significant changes in the peak fleroxacin concentration in plasma (6.3 +/- 1.2 versus 6.2 +/- 1.9 mg/liter), time to maximum concentration of fleroxacin in plasma (1.1 +/- 0.9 versus 1.3 +/- 1.1 h), or renal clearance (58.3 +/- 16.4 versus 61.9 +/- 19.2 ml/min). The area under the curve AUC (71.4 +/- 15.8 versus 62.2 +/- 13.7 mg.h/liter) and the terminal half-life of fleroxacin (11.4 +/- 2.2 versus 9.2 +/- 1.1 h) decreased (P < 0.05), while the total plasma clearance increased from 97.7 +/- 21.6 to 112.3 +/- 25.8 ml/min (P < 0.01). Despite being statistically significant, this 15% increase in total plasma clearance does not appear to be clinically relevant. Metabolic clearance by N demethylation was increased ( 6.9 +/- 2.4 versus 12.5 +/- 3.2 ml/min; P < 0.01), whereas clearance by N oxidation did not change (5.8 +/- 1.1 versus 5.8 +/- 1.5 ml/min). Fleroxacin elimination was slightly increased (about 15%) through induction of metabolic clearance to N-demethyl-fleroxacin. Since fleroxacin levels remained above the MIC for 90% of the tested isolates of methicillin-susceptible S. aureus for at least 24 h, dose adjustment does not appear necessary, at least for short-term treatments.

Penetration of fleroxacin into body tissues and fluids.

Concentrations of fleroxacin in human body fluids and tissues were studied to obtain information about the efficacy of the drug at the site of infection and the ratio of fleroxacin concentrations in tissue or fluid versus those in plasma as a measure of the extent of penetration. Samples of body fluids and tissues were obtained at various intervals after oral administration, and fleroxacin concentrations were determined by high-performance liquid chromatography. After administration of the standard dose of 400 mg once daily, the maximal plasma concentrations were 5-7 mg/L at steady-state and the minimal concentrations were approximately 1 mg/L at the end of the dosing interval. In most biologic specimens, such as myometrium, fallopian tube, bile bladder wall, bone, tonsils, maxillary sinus mucosa, prostatic adenoma, sputum, inflammatory fluid, synovia, lymph, saliva, and tears, the levels of fleroxacin were similar to those in plasma. In bile, nasal secretions, seminal fluid, lung, bronchial mucosa, and ovaries, the drug concentrations were 2-3 times higher than those in plasma. Penetration of fleroxacin into fat, lens, bronchial secretions, sweat, and aqueous humor was limited, with drug levels reaching only 10-40% of the concomitant levels in plasma. The measured concentration ratios did not vary markedly with time, and the decline in drug concentrations in tissues and fluids was generally parallel to that in plasma. The breakpoint for susceptibility is 1 micrograms/mL. The susceptibility breakpoint was exceeded by the drug concentration in plasma for the entire dosing interval and was also reached or exceeded in most body tissues and fluids.

Pharmacokinetics of fleroxacin in renal impairment.

Fleroxacin is excreted primarily via the kidneys in its unchanged form, and therefore renal impairment has a major influence on the pharmacokinetics of this drug. This study examined the pharmacokinetics of oral and intravenous fleroxacin in patients with renal impairment. Patients with renal disease (mean glomerular filtration rate [GFR], 22 mL/min) and healthy subjects (mean GFR, 100 mL/min) received 400 mg of fleroxacin orally and 100 mg of fleroxacin intravenously in a crossover design. Serial blood samples and a complete urine collection were obtained for > or = 72 hours after dosing. Unchanged drug in plasma and urine was determined by reverse-phase high-performance liquid chromatography. Fleroxacin was well tolerated by all study participants. Renal impairment had no influence on the complete absorption of fleroxacin from the gastrointestinal tract, the maximal plasma concentration, and the steady-state volume of distribution (Vd-ss > 1 L/kg). However, systemic clearance in patients was significantly decreased (p < 0.05) to 44.4 mL/min compared with 87.1 mL/min in healthy subjects. This decrease could be ascribed to a reduction in renal clearance from 59.1 mL/min in healthy subjects to 8.8 mL/min in patients. Metabolic clearance was not reduced significantly. As a consequence of reduced clearance, the mean elimination half-life in patients increased from 13.6 hours to 21.4 hours and the area under the concentration-time curve from 87.0 mg.h/L to 170.5 mg.h/L. To avoid an unacceptable accumulation of fleroxacin in the body during multiple dosing, the following dose adjustment was recommended: patients with renal disease whose GFR is < 40 mL/min should receive the normal loading dose, i.e., 400 mg, but should receive maintenance doses that are reduced by 50%, i.e., to 200 mg.

Penetration of fleroxacin into breast milk and pharmacokinetics in lactating women.

Fleroxacin was administered to seven lactating women as a single oral dose of 400 mg. Plasma, urine, and milk samples were collected for up to 48 h after administration. Drug concentrations were determined by a reversed-phase high-pressure liquid chromatography method and were used for the pharmacokinetic evaluation. At approximately 2 h after oral administration, a maximum concentration of 5.6 mg/liter was determined in plasma; the area under the plasma concentration-time curve (AUC) amounted to 70.3 mg.h/liter, and the elimination half-life in the postdistributive phase was 8 h. Total systemic clearance was 97.3 ml/min, and urinary excretion was 38% of the dose within 48 h. In addition, 8.6% of the N-demethyl metabolite and 4.4% of the N-oxide metabolite were recovered from urine. In comparison with previous results obtained with healthy male volunteers, the time to reach maximum concentrations in plasma was twice as long in the nursing women, and total clearance as well as urinary elimination were reduced by 25%. In breast milk, the mean maximum concentration was 3.5 mg/liter, which was reached 2.6 h after drug administration. The elimination half-life of fleroxacin in milk was identical to that in plasma, and the AUC reached 43.3 mg.h/liter. On the basis of the comparison of the AUC in milk versus the AUC in plasma, the proportion of fleroxacin penetration into milk was 62%. The cumulative excretion in milk amounted to only 0.219 mg within 48 h. On the basis of an average daily intake of milk of a breast-fed child of 150 ml/kg of body weight, the maximum daily ingested fleroxacin dose would not exceed 10 mg. However, quinolones are known to induce arthropathy in juvenile animals, and therefore, administration of fleroxacin to breast-feeding women cannot be allowed.

Penetration of fleroxacin into human and animal tissues.

Fleroxacin concentrations in human and rat tissues were determined by HPLC following extraction with dichloromethane:isopropanol. This method yielded a high recovery of more than 85%. In the investigated tissues the fleroxacin levels were equal to or higher than those concomitantly measured in plasma. The concentration ratios 'tissue/plasma' were 1.6-2.7 for lung, 1.9-2.1 for muscle, 1.1-1.9 for gynaecological tissues and 1.2 for bone. Only in the case of fat and lens/eye lower ratios of 0.05-0.5 were found. The actual measured fleroxacin concentrations in most tissues and in plasma were high. Following oral administration of the recommended therapeutic dose of 400 mg, once daily, peak concentrations of 5-6 mg/l were reached in human plasma at steady state. Even 24 h after drug intake the fleroxacin level was still approximately 1 mg/l and thus in the range of the MIC90 values of susceptible bacteria causative for many types of tissue infections.