AI Article Synopsis
- The study evaluates plasma protein binding (PB) of 11 diverse drugs using a non-radiolabeled equilibrium dialysis method, which overcomes limitations associated with traditional radiolabeled techniques.
- Recent regulatory expectations emphasize the need for quantitative determination of the fraction unbound (Fu) in drug development, making this approach particularly relevant.
- The methodology detailed in the study not only provides reliable Fu measurements for highly-bound drugs but also sets a standardized protocol that adheres to stringent bioanalytical requirements for drug development.
Article Abstract
Definitive plasma protein binding (PB) studies in drug development are routinely conducted with radiolabeled material, where the radiochemical purity limits quantitative PB measurement. Recent and emerging regulatory guidances increasingly expect quantitative determination of the fraction unbound (Fu) for key decision making. In the present study, PB of 11 structurally- and therapeutically-diverse drugs spanning the full range of plasma binding was determined by equilibrium dialysis of non-radiolabeled compound and was validated against the respective definitive values obtained by accepted radiolabeled protocols. The extent of plasma binding was in agreement with the radiolabeled studies; however, the methodology reported herein enables reliable quantification of Fu values for highly-bound drugs and is not limited by the radiochemical purity. In order to meet the rigor of a development study, equilibrium dialysis of unlabeled drug must be supported by an appropriately validated bioanalytical method along with studies to determine compound solubility and stability in matrix and dialysis buffer, nonspecific binding to the dialysis device, and ability to achieve equilibrium in the absence of protein. The presented methodology establishes an experimental protocol for definitive PB measurement, which enables quantitative determination of low Fu values, necessary for navigation of new regulatory guidances in clinical drug development.
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| http://dx.doi.org/10.1002/jps.22452 | DOI Listing |
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