Microdosing: a valuable tool for accelerating drug development and the role of bioanalytical methods in meeting the challenge.

The concept of specifically determining the clinical pharmacokinetics of a compound using a very low nonpharmacologically active dose (microdose) with an abridged safety and chemistry, manufacturing and control package is relatively new. It is not without its controversy and it is still a subject of discussion. Here, the rationale and application of this approach are examined, together with the regulatory and bioanalytical framework. There are two bioanalytical methods commonly used for human microdosing studies: LC-MS/MS and accelerator MS (AMS). Each method has advantages and disadvantages with the choice of instrumentation being closely tied to the primary objective(s) of the study. If a rapid decision is required on the appropriateness of a pharmacokinetic profile or if a choice is needed from a series of compounds, especially before radiolabeled material is available, LC-MS/MS may be preferable. However, if extreme sensitivity is required, data are required on all drug-related material and metabolites, or a simultaneous intravenous microdose is used to determine absolute bioavailability (sometimes referred to as microtracing), AMS becomes the analytical method of choice. Examples are provided of microdosing studies utilizing both of these bioanalytical techniques. It is emphasized that microdosing is only one tool in the drug developer's tool box and it should be used in the context of all available data. However, when used appropriately, microdosing is a valuable tool, bridging between lead optimization and early clinical development.

Involvement of human UGT2B7 and 2B15 in rofecoxib metabolism.

O-Glucuronidation of 5-hydroxyrofecoxib is the major biotransformation pathway of rofecoxib in human, rat, and dog. The glucuronide conjugate is also involved in the reversible metabolism of rofecoxib in rat and human. Atypical bimodal phenomena were observed in their plasma concentration-time curves with a large variability among different human subjects. It is unclear which family members of human UDP-glucuronosyltransferases (UGT) are involved in the formation of the glucuronide. O-Glucuronidation of 5-hydroxyrofecoxib by human liver microsomes and eight cDNA-expressed human UGT isoforms were investigated. Human liver microsomes formed 5-hydroxyrofecoxib glucuronide with apparent V(max) value of 1736 pmol/min/mg of protein and K(m) value of 44.2 microM. Eight individual cDNA-expressed human UGT isozymes (1A1, 1A3, 1A4, 1A6, 1A8, 1A9, 2B7, and 2B15) were evaluated for glucuronidation of 5-hydroxyrofecoxib. Among them UGT2B15 exhibited the highest metabolism rate with apparent V(max) value of 286 pmol/min/mg of protein and K(m) value of 16.1 microM, whereas UGT2B7 showed apparent V(max) value of 47.1 pmol/min/mg of protein and K(m) value of 41.6 microM. These results indicated that human UGT2B15 has the highest level of activity for catalyzing the glucuronidation of 5-hydroxyrofecoxib. Because polymorphisms have been identified in human UGT2B7, 2B15 genes and O-glucuronidation of 5-hydroxyrofecoxib plays a major role in biotransformation of rofecoxib, it is possible that human UGT2B7 and 2B15 polymorphisms for O-glucuronidation of 5-hydroxyrofecoxib are responsible for the high variability in bimodal patterns in human plasma concentration-time curves.