Use of P0 was found to improve the correlation as compared to the conventional in vitro Papp ( Avdeef, 2011). In Avdeef (2011), the IVIVC P0 analysis for published data from porcine models gave a correlation coefficient, r2 of 0.58 (P < 0.001).
In the present study, the r2 improved slightly from 0.58 to 0.61 for the pooled data, for a total of 35 measurements (22 compounds). The r2 obtained for the P0 IVIVC analysis in the present study is lower than reported for an in vitro bovine BBB co-culture model ( Lundquist et al., 2002 and Cecchelli et al., 2007). In those studies, linear correlation was tested for in vitro Papp vs. in vivo BUI data of ten compounds; r2 of 0.86 was reported. The lower r2 in the present study could result from uncertainties in P0 derivation, e.g. when the GDC-0199 price measured data were too close to one of the DRW boundaries (either
ABL or paracellular limit), or when judgement has to be made to determine pKaFLUX AUY-922 price from assays for ionizable compounds conducted at a single pH of 7.4, which is common for BBB research. The low r2 may also reflect the use of pCEL-X predicted in situ P0 values (acetylsalicylic acid and neramexane) and Caco-2 values (dexamethasone and metoprolol) to fill in gaps in the rodent in situ brain perfusion database. The focus of the applications so far has been to derive or predict the transcellular passive permeability in vivo. Hence, in situ data for the training set were selected from studies which used transporter knock-out animals, transporter inhibitors or high concentration of compounds to saturate transporters Metalloexopeptidase ( Dagenais et al., 2009). Compounds reported to show saturable transport were excluded. In the present study, the assays for uptake compounds were not conducted in the presence of inhibitors or saturating concentrations.
Therefore, the permeability values obtained were in some cases different from predictions. The differences in transporter expression in different species (pig and rodent) and also in different models used i.e. in vitro and in vivo could also influence the r2. In the present study, the data collected reflect evolution of the in vitro PBEC model from a low TEER cell monolayer (below 200 Ω cm2) to high TEER cell monolayer (>1000 Ω cm2) used for permeability assays and the new knowledge of the restrictive effect of polyester filter membrane (Transwell®-Clear) on permeability of lipophilic compounds. The cell monolayer tightness and filter boundary define the DRW which influences P0 derivation, hence could also influence r2. The larger numbers of compounds in the IVIVC analysis in the present study cover a wider chemical space compared to the correlation analysis of ten compounds reported by Lundquist et al. (2002) which will also influence r2.