Investigation of the metabolism of rufinamide and its interaction with valproate.

Rufinamide was evaluated in vitro to determine which enzyme(s) are responsible for rufinamide hydrolysis and whether valproate, one of its metabolites (valproyl-CoA), and/or the rufinamide hydrolysis product (CGP 47292) could inhibit hydrolysis. Rufinamide hydrolysis was mediated primarily by human carboxylesterase (hCE) 1 and was nonsaturable up to 500 µM. Two-thirds of rufinamide hydrolysis was estimated to occur in human microsomes and one-third in cytosol. Valproate was a selective inhibitor for hCE1 compared to hCE2 and inhibition had a greater impact on rufinamide hydrolysis in microsomes than in cytosol. Valproyl-CoA caused similar inhibition of rufinamide hydrolysis in both microsomes and cytosol. Carboxylesterases were not significantly inhibited by CGP 47292. Inhibition of in vitro rufinamide hydrolysis by valproate could offer an explanation for the observed in vivo drug-drug interaction between the two antiepileptic drugs.

Pharmacokinetic drug-drug interaction of the novel anticancer agent E7070 and acenocoumarol.

E7070 is a novel sulfonamide anticancer agent that arrests cancer cells at the G1/S boundary of the cell cycle. Three patients receiving chronic therapy with the oral anticoagulant acenocoumarol experienced bleeding and/or a prolonged prothrombin time after treatment with E7070 at a dose of 700 mg/m2 given as a 1-h infusion. In vitro studies have shown that E7070 has the potential to inhibit several cytochrome P450 (CYP)-enzymes, including CYP2C9, CYP2C19, CYP2D6, CYP2E1, and CYP3A4. The major enzyme involved in the metabolism of acenocoumarol in man is CYP2C9. This study was performed to investigate the interaction between E7070 and acenocoumarol. Blood samples were obtained from two patients receiving daily oral maintenance treatment with acenocoumarol both prior to and following treatment with E7070. In addition, we incubated acenocoumarol enantiomers with pooled human microsomes with and without E7070 and measured the in vitro plasma protein binding of acenocoumarol after incubation with E7070. Pharmacokinetic parameters of acenocoumarol were calculated by noncompartmental analysis and revealed that in both patients the area under the concentration-time curve up to 24 h after the acenocoumarol administration was higher following E7070 (2.56 and 1.58 h*micromol/L) compared to the systemic exposure in the absence of E7070 (1.87 and 1.23 h*micromol/l). The formation of acenocoumarol metabolites was retarded by E7070 at already low concentrations (2.1 microM). The plasma protein binding of acenocoumarol was reduced at higher concentrations of E7070 (259 microM). These results indicate that E7070 may primarily interact with acenocoumarol by reducing its systemic clearance. Displacement of acenocoumarol's plasma protein binding by E7070 may also occur but to a minor extent. In the absence of careful monitoring this drug-drug interaction may result in hypoprothrombinemia and a hemorrhagic tendency.