Circadian variations in exsorptive transport: in situ intestinal perfusion data and in vivo relevance.

The circadian timing system (CTS) governs the 24-h rhythm of the organism and, hence, also main pathways responsible for drug pharmacokinetics. P-glycoprotein (P-gp) is a drug transporter that plays a pivotal role in drug absorption, distribution, and elimination, and temporal changes in its activity may affect input, output, activity, and toxicity profile of drugs. In the current study, the influence of different circadian stages on the overall intestinal permeability (P(eff)) of the P-gp substrates talinolol and losartan was evaluated in in situ intestinal perfusion studies in rats. Additionally, in vivo studies in rats were performed by employing the P-gp probe talinolol during the day (nonactive) and night (active) period in rats. Effective intestinal permeabilities of talinolol and losartan were smaller in studies performed during the night (p < .05), indicating that P-gp-dependent intestinal secretion is greater during the nighttime activity span than daytime rest span of the animals. P-gp modulators vinblastine and PSC833 led to a significant decrease of talinolol and losartan exsorption in the intestinal segments as compared with control groups. Strikingly, the permeability-enhancing effect of vinblastine and PSC833 was higher with night perfusions, for both talinolol and losartan. In vivo studies performed with talinolol revealed-consistent with the in situ studies (P(eff) day > night)-a day vs. night difference in the oral availability of talinolol in the group of male rats in terms of the area under the curve (AUC) data (AUC(day) > AUC(night)). The P-gp modulator vinblastine significantly increased talinolol AUC(day) (p < .05), whereas only a weak vinblastine effect was seen in night. According to the in situ data, the functional activity of P-gp was regulated by the CTS in jejunum and ileum, which are major intestinal segments for energy-dependent efflux. In conclusion, circadian rhythms may affect carrier-mediated active efflux and play a role in the absorption process. In addition to daily rhythms in P-gp activity in rat intestine, the in vivo studies indicate that absorption-, distribution-, metabolism-, and elimination-relevant rhythms may be involved in the circadian kinetics of the drug, besides transporter-dependent efflux, such well-known aspects as metabolic or renal clearance or motility. Since this also holds true for a potentially interacting second compound (modulator), modulator effects should be evaluated carefully in transporter related drug-drug interactions.

Lipophilicities of baclofen ester prodrugs correlate with affinities to the ATP-dependent efflux pump P-glycoprotein: relevance for their permeation across the blood-brain barrier?

PURPOSE: Distribution to the effect site is a prerequisite for the therapeutic effect and determined by physicochemical properties and affinities to inside- and outside-directed membrane transporters. Based on the hypothesis that lipophilic esters of the GABA-derivative baclofen have a higher affinity to brain tissue, baclofen esters (methyl, ethyl, 1-propyl, 2-propyl, butyl) were studied regarding their penetration through the blood-brain barrier and their affinities to P-glycoprotein (P-gp). METHODS: Octanol-water distribution coefficients (D) served as lipophilicity parameters. Blood and brain concentrations of baclofen and its methyl ester were determined in vivo in rats following intraperitoneal administration. Affinities to P-gp were evaluated using a radioligand binding assay based on P-gp-overexpressing cells and [3H]-talinolol as radioligand. RESULTS: Log D values for baclofen and ester derivatives were -0.96 (baclofen), 0.48 (methyl), 0.77 (ethyl), 1.31 (1-propyl), 1.27 (2-propyl), and 1.42 (butyl). In-vitro studies yielded negligible affinity of baclofen to P-gp, whereas IC50-values for the esters ranged between 1300 microM (methyl) and 290 microM (2-propyl). Affinity parameters correlated well with the lipophilicity parameters. CONCLUSION: Despite the P-gp affinity, brain concentrations of methyl ester were significantly higher than those of baclofen, however, baclofen levels following administration of the ester were smaller than with baclofen administration indicating only partial hydrolysis.