Utility of unbound plasma drug levels and P-glycoprotein transport data in prediction of central nervous system exposure

Drug concentrations in cerebrospinal fluid have been assumed to be a natural surrogate for total drug exposures in the central nervous system. The present communication reports a data set from a study of 30 compounds in mice. An attempt was made to correlate cerebrospinal fluid and unbound plasma drug concentrations via incorporation of in vitro P-glycoprotein (Pgp)-mediated transport data. 2. Pgp-deficient (Pgp -/-) and wild-type mice were dosed with compounds of interest by oral gavage (orally) at 5 mg kg −1 . Plasma and cerebrospinal fluid samples were collected at 1 h post-dosing, and analysed by liquid chromatography-tandem mass spectrometry (LC-MS/MS) for drug concentrations. Mouse and human Pgp-mediated transport were evaluated in vitro by a bi-directional (B to A and A to B) transport assay using LLC-PK1 cells expressing mouse (mdr1a) and human (MDR1) forms of Pgp, respectively. 3. Compounds with B to A/A to B transport ratios < 2 were defined as non-substrates of Pgp, whereas those exhibiting B to A/A to B transport ratios ≥2 were considered Pgp substrates. Plasma protein bind- ing was also determined in vitro via equilibrium dialysis. Of the 30 compounds, 13 were identified to be mouse Pgp substrates, all of which were also human Pgp substrates, demonstrating a good agreement between mouse and human data. 4. In Pgp wild-type mice, the unbound plasma and cerebrospinal fluid concentrations of the non-Pgp sub - strates correlated well, with a regression slope of approximately 1.0. A similar relationship existed for Pgp substrates in Pgp -/- mice. On the other hand, an improved correlation of cerebrospinal fluid and systemic exposures of the Pgp substrates in Pgp wild-type mice was observed when the unbound plasma concentrations were normalized to the corresponding B to A/A to B transport ratios. 5. These results reinforce the premise that a combined use of unbound plasma drug concentrations and in vitro Pgp transport data may be of value for the estimation of central nervous system exposures.