Biliary excretion of ximelagatran and its metabolites and the influence of erythromycin following intraintestinal administration to healthy volunteers.

The biliary excretion of the oral thrombin inhibitor ximelagatran and its metabolites was investigated by using duodenal aspiration in healthy volunteers following intraintestinal dosing. In the first investigation, radiolabeled [(14)C]ximelagatran was administered, enabling quantification of the biliary excretion and identification of metabolites in the bile. In the second study, the effect of erythromycin on the biliary clearance of ximelagatran and its metabolites was investigated to clarify the reported ximelagatran-erythromycin interaction. Approximately 4% of the intraintestinal dose was excreted into bile with ximelagatran and its active form, melagatran, being the most abundant compounds. Four novel ximelagatran metabolites were identified in bile (<0.1% of dose). Erythromycin changed the pharmacokinetics of ximelagatran and its metabolites, with an elevated ximelagatran (78% increase), OH-melagatran (89% increase), and melagatran (86% increase) plasma exposure and higher peak plasma concentrations of the compounds being measured. In parallel, the biliary clearance was moderately reduced. The results suggest that inhibition of hepatobiliary transport is a likely mechanism for the interaction between erythromycin and ximelagatran. Furthermore, the study demonstrated the value of direct bile sampling in humans for the identification of primary biliary metabolites.

Intestinal and hepatobiliary transport of ximelagatran and its metabolites in pigs.

The direct thrombin inhibitor melagatran is formed from ximelagatran via two intermediate metabolites, OH-melagatran and ethylmelagatran. The biotransformation of ximelagatran does not involve cytochrome P450 isoenzymes, and it has been suggested that a reported interaction with erythromycin may instead be mediated by transport proteins. A pig model that simultaneously enables bile collection, sampling from three blood vessels and perfusion of a jejunal segment, was used to investigate the biotransformation of ximelagatran and the effect of erythromycin on the intestinal and hepatobiliary transport of ximelagatran and its metabolites. The pigs received enteral ximelagatran (n = 6), enteral ximelagatran together with erythromycin (n = 6), i.v. ximelagatran (n = 4), or i.v. melagatran (n = 4). The plasma exposure of the intermediates was found to depend on the route of ximelagatran administration. Erythromycin increased the area under the plasma concentration-time curve (AUC) of melagatran by 45% and reduced its biliary clearance from 3.0 +/- 1.3 to 1.5 +/- 1.1 ml/min/kg. Extensive biliary exposure of melagatran and ethylmelagatran, mediated by active transport, was evident from the 100- and 1000-fold greater AUC, respectively, in bile than in plasma. Intestinal efflux transporters seemed to be of minor importance for the disposition of ximelagatran and its metabolites considering the high estimated f(abs) of ximelagatran (80 +/- 20%) and the negligible amount of the compounds excreted in the perfused intestinal segment. These findings suggest that transporters located at the sinusoidal and/or canalicular membranes of hepatocytes determine the hepatic disposition of ximelagatran and its metabolites, and are likely to mediate the ximelagatran-erythromycin pharmacokinetic interaction.

Pharmacokinetics and pharmacodynamics of the oral direct thrombin inhibitor ximelagatran co-administered with different classes of antibiotics in healthy volunteers.

OBJECTIVE: To study the effects of amoxicillin, doxycycline, ciprofloxacin, azithromycin, and cefuroxime on the pharmacokinetics and pharmacodynamics of melagatran, the active form of the oral direct thrombin inhibitor ximelagatran, which is a substrate for the P-glycoprotein pump (P-gp) transporter but is not metabolized by the cytochrome P450 (CYP450) enzyme system. METHODS: Five parallel groups of 16 healthy volunteers received two sequential treatments. The first treatment was a single 36-mg dose of ximelagatran. During the second treatment period, one of the above antibiotics was given on days 1-5 after a washout of at least 2 days. A single 36-mg oral dose of ximelagatran was given on the mornings of days 1 and 5 of the second treatment period. RESULTS: No pharmacokinetic interactions were detected between ximelagatran and amoxicillin, doxycycline, or ciprofloxacin as the least-squares geometric mean treatment ratio of ximelagatran with-to-without antibiotic fell within the intervals of 0.80-1.25 for the area under the curve (AUC) and 0.7-1.43 for C(max). After co-administration with azithromycin, the least square mean ratio with-to-without antibiotic for AUC of melagatran was 1.60 (90% CI, 1.40-1.82) on day 1 and 1.41 (90% CI, 1.24-1.61) on day 5. For melagatran C(max), the corresponding ratios were 1.63 (90% CI, 1.38-1.92) and 1.40 (90% CI, 1.18-1.66). After co-administration with cefuroxime, the ratios were 1.23 (90% CI, 1.07-1.42) and 1.16 (90% CI, 0.972-1.38) for AUC and 1.33 (90% CI, 1.07-1.66) and 1.19 (90%CI, 0.888-1.58) for C(max) of melagatran. Co-administration with the antibiotics did not change mean time to C(max), half-life, or renal clearance of melagatran. The melagatran plasma concentration-response relationship for activated partial thromboplastin time (APTT) prolongation was not altered by any of the studied antibiotics, but the increased plasma concentrations of melagatran after co-administration of ximelagatran with azithromycin resulted in a minor increase in the mean maximum APTT of about 15%. CONCLUSION: The pharmacokinetics of ximelagatran were not affected by amoxicillin, doxycycline, or ciprofloxacin. Melagatran exposure was increased when ximelagatran was co-administered with azithromycin and, to a lesser extent, with cefuroxime. APTT was not significantly altered by any of the antibiotics.

Determination of ximelagatran, melagatran and two intermediary metabolites in plasma by mixed-mode solid phase extraction and LC-MS/MS.

An analytical method was developed for the determination of ximelagatran, an oral direct thrombin inhibitor, its active metabolite melagatran, and the two intermediate metabolites, OH-melagatran and ethyl-melagatran in human plasma. Extraction of plasma was carried out on a mixed mode bonded sorbent material (C8/SO(3)(-)). All four analytes, including their isotope-labelled internal standards, were eluted at high ionic strength with a mixture of 50% methanol and 50% buffer (0.25 M ammonium acetate and 0.05 M formic acid, pH 5.3) with an extraction recovery above 80%. The extracts were demonstrated to be clean in terms of a low concentration of albumin and lysoPC. The sample extraction was fully automated and performed in 96-well plates using a Tecan Genesis pipetting robot. Analysis of the extracts were performed with liquid chromatography followed by positive electrospray ionization mass spectrometry. The low organic content and the low pH of the extracts allowed for, after dilution 1:3 with buffer, direct injection onto the LC-column. The four analytes were separated on a C18 analytical LC-column using gradient elution with the acetonitrile concentration varying from 10 to 30% (v/v) and the ammonium acetate and acetic acid concentration kept constant at 10 and 5 mmol/L, respectively, at a flow rate of 0.75 mL/min. Linearity was achieved over the calibrated range 0.010-4.0 micromol/L with accuracy and relative standard deviation in the range 96.9-101.2% and 6.6-17.1%, respectively at LLOQ, and in the range 94.7-102.6% and 2.7-6.8%, respectively at concentrations above 3 x LLOQ. The method replaces a manual method, and displays the advantages of having a fully automated sample clean-up, no evaporation/reconstitution step, high recovery, and complete LC-separation of all four analytes.

Influence of age on the pharmacokinetics and pharmacodynamics of ximelagatran, an oral direct thrombin inhibitor.

OBJECTIVE: To investigate the influence of age on the pharmacokinetics and pharmacodynamics of ximelagatran. STUDY DESIGN: This was an open-label, randomised, 3 x 3 crossover study with 4 study days, separated by washout periods of 7 days. SUBJECTS: Subjects comprised 6 healthy young men (aged 20-27 years) and 12 healthy older men and women (aged 56-70 years). METHODS: All subjects received a 2mg intravenous infusion of melagatran over 10 minutes followed, in randomised sequence, by a 20 mg immediate-release tablet of ximelagatran with breakfast, a 20 mg immediate-release tablet of ximelagatran while fasting, and a 7.5 mg subcutaneous injection of ximelagatran. The primary variables were the plasma concentration of melagatran, the active form of ximelagatran, and the activated partial thromboplastin time (APTT), an ex vivo coagulation time measurement used to demonstrate inhibition of thrombin. RESULTS: After oral and subcutaneous administration, ximelagatran was rapidly absorbed and biotransformed to melagatran, its active form and the dominant compound in plasma. The metabolite pattern in plasma and urine was similar in young and older subjects after both oral and subcutaneous administration of ximelagatran clearance of melagatran was correlated with renal function, resulting in about 40% (after intravenous melagatran) to 60% (after oral and subcutaneous ximelagatran) higher melagatran exposure in the older than in the young subjects. Renal clearance of melagatran, was 7.7 L/h and 4.9 L/h in the younger and older subjects, respectively. The interindividual variability inn the area under the melagatran plasma concentration-time curve was low following all regimens (coefficient variation 12-25%). The mean bioavailability of melagatran in young and older subjects was approximately 18 and 12% , respectively, following oral administration of ximalagratan, and 38 and 45%, respectively, following subcutaneous administration of ximelagatran. The bioavailability of melagatran following oral administration of ximelagatran was unaffected by whether subjects were fed or fasting, although the plasma concentration of melagatran peaked about 1 hour later under fed than fasting conditions, due to gastric emptying of the immediate-release tablet formulation used. The APTT as prolonged with increasing melagatran plasma concentration-effect relationship was independent of age. CONCLUSIONS: There were no age-dependent differences in the absorption and biotransformation of ximelagatran, and the observed differences in exposure to melagatran can be explained by differences in renal function between the young and older subjects.

Determination of ximelagatran, an oral direct thrombin inhibitor, its active metabolite melagatran, and the intermediate metabolites, in biological samples by liquid chromatography-mass spectrometry.

Analytical methods for the determination of ximelagatran, an oral direct thrombin inhibitor, its active metabolite melagatran, and intermediate metabolites, melagatran hydroxyamidine and melagatran ethyl ester, in biological samples by liquid chromatography (LC) positive electrospray ionization mass spectrometry (MS) using selected reaction monitoring are described. Isolation from human plasma was achieved by solid-phase extraction on octylsilica. Analytes and isotope-labelled internal standards were separated by LC utilising a C(18) analytical column and a mobile phase comprising acetonitrile-4 mmol/l ammonium acetate (35:65, v/v) containing 0.1% formic acid, at a flow-rate of 0.75 ml/min. Absolute recovery was approximately 80% for ximelagatran, approximately 60% for melagatran ethyl ester and >90% for melagatran and melagatran hydroxyamidine. Limit of quantification was 10 nmol/l, with a relative standard deviation <20% for each analyte and <5% above 100 nmol/l. Procedures for determination of these analytes in human urine and breast milk, plus whole blood from rat and mouse are also described.

Determination of melagatran, a novel, direct thrombin inhibitor, in human plasma and urine by liquid chromatography-mass spectrometry.

Analytical methods for the determination of melagatran (H 319/68) in biological samples by liquid chromatography (LC)-positive electrospray ionization mass spectrometry using multiple reaction monitoring are described. Melagatran in plasma was isolated by solid-phase extraction on octylsilica, either in separate extraction tubes or in 96-well plates. Absolute recovery of melagatran from plasma was >92%. Melagatran and the internal standard, H 319/68 D2 13C2, were separated from other sample components by LC utilizing a C18 stationary phase and a mobile phase comprising 35% acetonitrile and 0.08% formic acid in 0.0013 mol/l ammonium acetate solution. After dilution, urine was injected directly onto the LC column and subjected to gradient LC. The relative standard deviation was 1-5% for concentrations above the limit of quantification, which was estimated for plasma at 10 or 25 nmol/l for sample volumes of 500 or 200 microl, respectively, and 100 nmol/l for urine.