Fexofenadine Enantiomers Research Articles

Chiral Transplacental Pharmacokinetics of Fexofenadine: Impact of P-Glycoprotein Inhibitor Fluoxetine Using the Human Placental Perfusion Model.

Fexofenadine is a well-identified in vivo probe substrate of P-glycoprotein (P-gp) and/or organic anion transporting polypeptide (OATP). This work aimed to investigate the transplacental pharmacokinetics of fexofenadine enantiomers with and without the selective P-gp inhibitor fluoxetine. The chiral transplacental pharmacokinetics of fexofenadine-fluoxetine interaction was determined using the ex vivo human placenta perfusion model (n = 4). In the Control period, racemic fexofenadine (75ng of each enantiomer/ml) was added in the maternal circuit. In the Interaction period, racemic fluoxetine (50ng of each enantiomer/mL) and racemic fexofenadine (75ng of each enantiomer/mL) were added to the maternal circulation. In both periods, maternal and fetal perfusate samples were taken over 90min. The (S)-(-)- and (R)-(+)-fexofenadine fetal-to-maternal ratio values in Control and Interaction periods were similar (~0.18). The placental transfer rates were similar between (S)-(-)- and (R)-(+)-fexofenadine in both Control (0.0024 vs 0.0019min-1) and Interaction (0.0019 vs 0.0021min-1) periods. In both Control and Interaction periods, the enantiomeric fexofenadine ratios [R-(+)/S-(-)] were approximately 1. Our study showed a low extent, slow rate of non-enantioselective placental transfer of fexofenadine enantiomers, indicating a limited fetal fexofenadine exposure mediated by placental P-gp and/or OATP2B1. The fluoxetine interaction did not affect the non-enantioselective transplacental transfer of fexofenadine. The ex vivo placental perfusion model accurately predicts in vivo placental transfer of fexofenadine enantiomers with remarkably similar values (~0.17), and thus estimates the limited fetal exposure.

Chiral Discrimination of P-glycoprotein in Parturient Women: Effect of Fluoxetine on Maternal-Fetal Fexofenadine Pharmacokinetics.

Fluoxetine, antidepressant widely-used during pregnancy, is a selective inhibitor for P-glycoprotein (P-gp). Fexofenadine, an in vivo P-gp probe, is an antihistamine drug for seasonal allergic rhinitis and chronic urticaria treatment during pregnancy and it is available as a racemic mixture. This study evaluated the chiral discrimination of P-gp investigating the effect of fluoxetine on maternal-fetal pharmacokinetics of fexofenadine. Healthy parturient women received either a single oral dose of 60mg racemic fexofenadine (Control group; n = 8) or a single oral dose of 40mg racemic fluoxetine 3h before a single oral dose of 60mg racemic fexofenadine (Interaction group; n = 8). Maternal blood and urine samples were collected up to 48h after fexofenadine administration. At delivery, maternal-placental-fetal blood samples were collected. The maternal pharmacokinetics of fexofenadine was enantioselective (AUC0-∞R-(+)/S-(-) ~ 1.5) in both control and interaction groups. Fluoxetine increased AUC0-∞ (267.7 vs 376.1ng.h/mL) and decreased oral total clearance (105.1 vs 74.4L/h) only of S-(-)-fexofenadine, whereas the renal clearance were reduced for both enantiomers, suggesting that the intestinal P-gp-mediated transport of S-(-)-fexofenadine is influenced by fluoxetine to a greater extent that the R-(+)-fexofenadine. However, the transplacental transfer of fexofenadine is low (~16%), non-enantioselective and non-influenced by fluoxetine. A single oral dose of 40mg fluoxetine inhibited the intestinal P-gp mediated transport of S-(-)-fexofenadine to a greater extent than R-(+)-fexofenadine in parturient women. However, the placental P-gp did not discriminate fexofenadine enantiomers and was not inhibited by fluoxetine.

Direct chiral LC-MS/MS analysis of fexofenadine enantiomers in plasma and urine with application in a maternal-fetal pharmacokinetic study

This study shows the development and validation of two enantioselective LC-MS/MS methods for the determination of fexofenadine in biological matrices including the elution order determination. Plasma (200 µL) or urine (50 µL) aliquots were added to the internal standard solution [(S)-(−)-metoprolol] and extracted in the acid medium with chloroform. Resolution of the (R)-(+)- and (S)-(−)-fexofenadine enantiomers was performed in a Chirobiotic V column. The methods showed linearity at the range of 0.025–100 ng/mL plasma and 0.02–10 µg/mL urine for each fexofenadine enantiomer. These methods were applied to the maternal-fetal pharmacokinetics of fexofenadine enantiomers in plasma and urine of parturient women (n = 8) treated with a single oral 60 mg dose of racemic fexofenadine. Enantiomeric ratio in plasma (AUC0−∞(R)-(+)/(S)-(−)) was close to 1.5, nevertheless in urine was closed to unity. The transplacental transfer was approximately 18% for both fexofenadine enantiomers. The enantioselective methods can also be useful in future clinical studies of chiral discrimination of drug transporters.

Influence of P-glycoprotein on the disposition of fexofenadine and its enantiomers.

P-glycoprotein (P-gp) is responsible for the efflux of a broad variety of human and veterinary drugs. Canine P-gp polymorphisms alter drug disposition and toxicity, but their impact on the disposition of enantiomeric drugs is unknown. Using fexofenadine as a model compound, we developed and validated HPLC-fluorescence methods to determine the effect of P-gp on the disposition of fexofenadine and its enantiomers. A chiral CD-Ph column was used for the separation of (R) and (S)-fexofenadine. Determination of racemic fexofenadine was achieved on an XDB-CN column. Fexofenadine and its enantiomers were detected by fluorescence at the excitation wavelength of 220 nm and emission wavelength of 300 nm. These methods were used to measure concentrations of fexofenadine and its enantiomers in Collie plasma after oral administration. This study demonstrates that P-gp prefers to transport (S)-fexofenadine, and P-gp deficiency causes the increase in both (R)-fexofenadine and (S)-fexofenadine in plasma. Racemic fexofenadine, (R)-fexofenadine and (S)-fexofenadine were increased in ABCB1-1Δ Collies (118.7, 72.0 and 48.3 ng/ml) compared to wild-type Collies (25.0, 16.5 and 7.7 ng/ml) at 1 h postadministration. The results demonstrate that the stereoselectivity of P-gp plays a key role in the disposition of fexofenadine enantiomers. The information derived from this drug model will be used to determine whether additional safety or efficacy requirements are necessary for enantiomeric drugs that would be used in dogs or humans.

The change of pharmacokinetics of fexofenadine enantiomers through the single and simultaneous grapefruit juice ingestion

The stereoselective pharmacokinetics of fexofenadine are associated with OATP2B1-mediated transport, and grapefruit juice (GFJ) is an inhibitor of OATP2B1. Therefore, in this study, we aimed to investigate whether and to what extent GFJ ingestion affected the pharmacokinetics of fexofenadine enantiomers in healthy subjects. In a randomized, two-phase, open-label, crossover study, 14 subjects received 60 mg of racemic fexofenadine simultaneously with water or GFJ. Ingestion of GFJ significantly decreased the areas under the plasma concentration-time curve (AUC0–24) for (R)- and (S)-fexofenadine by 39% and 52%, respectively. Subsequently, GFJ increased the mean R/S ratio of the AUC0–24 from 1.58 to 1.96 (P < 0.05). Although GFJ greatly reduced the amounts of (R)- and (S)-fexofenadine excreted into the urine (Ae0–24) by 52% and 61%, respectively, the mean R/S ratios of Ae0–24 and the renal clearances of both enantiomers were unchanged between the control and GFJ phases. GFJ, an OATP2B1 inhibitor, significantly reduced the plasma concentrations of fexofenadine enantiomers, exhibiting clinically moderate effects. The present results suggested that changes in OATP2B1 activity by GFJ may alter the stereoselective pharmacokinetics of fexofenadine and that reduced intestinal OATP2B1 activity may affect the stereoselectivity of fexofenadine.

Determinants of the stereoselective pharmacokinetics of fexofenadine

Drug transporters play an important role in the clinical pharmacokinetics of many therapeutic agents. Although it is estimated that about half of all therapeutic agents are chiral, there has been little information on the stereoselective pharmacokinetics related to drug transporters. This review focuses on the drug transporters contributing to the stereoselective pharmacokinetics of fexofenadine enantiomers in humans. Fexofenadine is administered clinically as a racemic mixture, and the plasma concentration of (R)-fexofenadine is about 1.5-fold higher than that of the (S)-enantiomer. Because fexofenadine is poorly metabolized by cytochrome P450s, its pharmacokinetics depends on its drug-transporter activities. First, we examined whether drug-transporter polymorphisms influence fexofenadine enantiomer pharmacokinetics. The findings suggested that a combination of multiple transporters involving organic anion transporting polypeptide (OATP) 2B1, P-glycoprotein (P-gp), and multidrug resistance-associated protein 2 (MRP2) react to stereoselective fexofenadine exposure. Subsequently, we evaluated the roles of P-gp and OATPs in fexofenadine enantiomer pharmacokinetics using these inducer/inhibitors. Coadministration of P-gp inducer/inhibitors significantly altered the pharmacokinetics of fexofenadine enantiomers. In addition, the OATP inhibitors rifampicin and apple juice also affected fexofenadine enantiomer pharmacokinetics. Moreover, in in vitro studies, the uptake of both fexofenadine enantiomers into OATP2B1 cRNA-injected oocytes was significantly higher than that into water-injected oocytes, and this effect was greater for (R)-fexofenadine. Taken together, these studies indicated that multiple transporters including P-gp, OATPs, and MRP2 play important roles in fexofenadine enantiomer pharmacokinetics. Furthermore, OATP2B1 is a key determinant of the stereoselective pharmacokinetics of fexofenadine, and drug transporters may have chiral discrimination ability.

Effects of multiple-dose rifampicin 450 mg on the pharmacokinetics of fexofenadine enantiomers in Japanese volunteers.

Rifampicin is a potent inducer of P-glycoprotein (P-gp) and inhibitor of organic anion-transporting polypeptides (OATPs), with fexofenadine acting as a substrate for both mechanisms. Simultaneous administration of single- or multiple-dose rifampicin 600 mg significantly increases the concentrations of fexofenadine enantiomers by inhibiting OATP transporters. However, the effects of rifampicin 450 mg are unknown. Here, we evaluated the effects of multiple doses of rifampicin 450 mg on the pharmacokinetics of fexofenadine enantiomers in healthy Japanese volunteers. In this randomized, two-phase, double-blind crossover study, 10 healthy volunteers received rifampicin 450 mg/day or placebo for 7 days. On day 7, fexofenadine 60 mg was co-administered simultaneously. Rifampicin significantly increased the mean area under the plasma concentration-time curve (AUC) of (R)- and (S)-fexofenadine (3.10-fold and 3.48-fold, respectively) and decreased the renal clearance of (R)- and (S)-fexofenadine (0.40-fold and 0.47-fold, respectively), causing marked differences in the mean amounts of these enantiomers excreted into the urine in the rifampicin phase (P < 0.001). These results indicated that multiple doses of rifampicin 450 mg may be sufficient to inhibit the renal influx transporter and OATP-mediated hepatic uptake of both enantiomers. Moreover, these effects may be greater than the P-gp-inductive effects of rifampicin. Therefore, the interactive mechanism of multidose rifampicin may occur through a combination of OATP and P-gp transporters, thereby altering the pharmacokinetics of fexofenadine enantiomers. In this study of rifampicin 450 mg, the interactive magnitude of the mean AUC values of fexofenadine enantiomers was higher than that observed in the previous study of rifampicin 600 mg, and no dose-dependent inhibitory effects of rifampicin were observed. These effects may be clinically significant in patients receiving fexofenadine and rifampicin.

Effects of one-time apple juice ingestion on the pharmacokinetics of fexofenadine enantiomers.

We examined the effect of a single apple juice intake on the pharmacokinetics of fexofenadine enantiomers in healthy Japanese subjects. In a randomized two phase, open-label crossover study, 14 subjects received 60mg of racemic fexofenadine simultaneously with water or apple juice. For the uptake studies, oocytes expressing organic anion-transporting polypeptide 2B1 (OATP2B1) were incubated with 100μM (R)- and (S)-fexofenadine in the presence or absence of 10% apple juice. One-time ingestion of apple juice significantly decreased the area under the plasma concentration-time curve (AUC0-24) for (R)- and (S)-fexofenadine by 49 and 59%, respectively, and prolonged the time to reach the maximum plasma concentration (t max) of both enantiomers (P < 0.001). Although apple juice greatly reduced the amount of (R)- and (S)-fexofenadine excretion into urine (Ae0-24) by 54 and 58%, respectively, the renal clearances of both enantiomers were unchanged between the control and apple juice phases. For in vitro uptake studies, the uptake of both fexofenadine enantiomers into OATP2B1 complementary RNA (cRNA)-injected oocytes was significantly higher than that into water-injected oocytes, and this effect was greater for (R)-fexofenadine. In addition, apple juice significantly decreased the uptake of both enantiomers into OATP2B1 cRNA-injected oocytes. These results suggest that OATP2B1 plays an important role in the stereoselective pharmacokinetics of fexofenadine and that one-time apple juice ingestion probably inhibits intestinal OATP2B1-mediated transport of both enantiomers. In addition, this study demonstrates that the OATP2B1 inhibition effect does not require repeated ingestion or a large volume of apple juice.

Establishment of reverse-phase high-performance liquid chromatography with chiral reagent derivatization for separation of fexofenadine enantiomers

To establish a precolumn chiral derivatization method for determination of fexofenadine enantiomers, a chiral substrate of OATP1B1, in cellular model. R-(+)-phenylethyl isocyanate was selected as chiral derivatization reagent, which was reacted with fexofenadine to form carbamate derivatives. Enantiomers were identified by LC/MS and separated by RP-HPLC. Under the experimental conditions, the fexofenadine enantiomers were separated completely. The standard curve was linear over the concentration range of 25-100 ng/ml (R(2)=0.9992, 0.9989). Accuracy was 101.1% and 98.3%, intra-precision was 2.4% and 3.1%, inter-precision was 3.1% and 4.0% for D1 and D2, respectively. The method established is sensitive and accurate for determination of fexofenadine enantiomers in cells.

Effect of Coadministration of Single and Multiple Doses of Rifampicin on the Pharmacokinetics of Fexofenadine Enantiomers in Healthy Subjects

The effect of rifampicin on the pharmacokinetics of fexofenadine enantiomers was examined in healthy subjects who received fexofenadine alone or with single or multiple doses of rifampicin (600 mg). A single coadministered dose of rifampicin significantly decreased the oral clearance (CL(tot)/F) and renal clearance (CL(r)) of S- and R-fexofenadine by 76 and 62%, and 73 and 62%, respectively. Even after multiple doses, rifampicin significantly decreased these parameters, although the effect on the CL(tot)/F was slightly blunted. Multiple doses of rifampicin abolished the difference in the CL(tot)/F of fexofenadine enantiomers, whereas the stereoselectivity in the CL(r) persisted. Rifampicin inhibited the uptake of fexofenadine enantiomers by human hepatocytes via organic anion transporter (OAT) OATP1B3 and its basal-to-apical transport in Caco-2 cells, but not OAT3-mediated or multidrug and toxic compound extrusion 1 (MATE1)-mediated transport. The plasma-unbound fraction of S-fexofenadine was 1.8 times higher than that of R-fexofenadine. The rifampicin-sensitive uptake by hepatocytes was 1.6 times higher for R-fexofenadine, whereas the transport activities by OATP1B3, OAT3, MATE1, or P-glycoprotein were identical for both enantiomers. S-fexofenadine is a more potent human histamine H1 receptor antagonist than R-fexofenadine. In conclusion, rifampicin has multiple interaction sites with fexofenadine, all of which contribute to increasing the area under the curve of fexofenadine when they are given simultaneously, to surpass the effect of the induction of P-glycoprotein elicited by multiple doses.

Enantioselective uptake of fexofenadine by Caco-2 cells as model intestinal epithelial cells

Fexofenadine contains a chiral carbon in its chemical structure and is orally administered as a racemic mixture. This study evaluated the selective uptake of fexofenadine enantiomers by Caco-2 cells as a model of intestinal epithelial cells. R(+)-fexofenadine or S(-)-fexofenadine was applied to Caco-2 cells, followed by incubation. After incubation, the amounts of fexofenadine enantiomers in cells were determined. The kinetic parameters for the uptake of fexofenadine enantiomers by Caco-2 cells were estimated using the Michaelis-Menten equation. The transporter-mediated uptake rate of R(+)-fexofenadine was 1.7-fold higher than that of S(-)-fexofenadine. The difference in transporter-mediated R(+)-fexofenadine and S(-)-fexofenadine uptake was completely diminished under ATP-depleted conditions and in the presence of organic anion transporter peptide (OATP) inhibitors. Also, a Dixon plot showed that each fexofenadine enantiomer was competitively inhibited by the other enantiomer. The ratio of R(+)-fexofenadine uptake to S(-)-fexofenadine uptake in the case of a racemic mixture was higher than that in the case of a single enantiomer. This study suggested that the selective absorption of fexofenadine enantiomers by intestinal epithelial cells might have been due to the selective uptake mediated by OATPs and that the difference in intestinal absorption was enhanced with a racemic mixture.

Carbamazepine differentially affects the pharmacokinetics of fexofenadine enantiomers

This aim of this study was to characterize the impact of the P-glycoprotein (P-gp) inducer, carbamazepine, on fexofenadine enantiomer pharmacokinetics. Twelve healthy volunteers initially received a 60mg dose of fexofenadine alone. Subsequently, a 100mg dose of carbamazepine was administered three times daily (300mg day(-1) ), and on day 7, fexofenadine was co-administered. Carbamazepine significantly decreased the area under the plasma concentration-time curve and the amount excreted into the urine of (S)- and (R)-fexofenadine. The P-gp inducer showed a greater effect on the pharmacokinetic parameters of (S)-fexofenadine. This study indicates that carbamazepine may alter the pharmacokinetics of fexofenadine enantiomers.

Influence of drug-transporter polymorphisms on the pharmacokinetics of fexofenadine enantiomers

This study investigated an association of SLCO (encoding organic anion-transporting polypeptides (OATP), 1B1, 1B3, and 2B1), ABCB1 (P-glycoprotein (P-gp)), ABCC2 multidrug resistance protein 2 (MRP2), and ABCG2 (breast cancer resistance protein (BCRP)) polymorphisms with fexofenadine enantiomer pharmacokinetics after an oral dose of fexofenadine (60 mg) in 24 healthy subjects.The area under the plasma concentration-time curve (AUC0–24) of S-fexofenadine, but not R-fexofenadine, was significantly lower in subjects with a SLCO2B1*1/*1 allele as compared to subjects with a *3 allele (p = 0.031).The AUC0–24 of S-fexofenadine was significantly lower in subjects with a wild-type combination of SLCO2B1*1/*1/ABCB1 1236CC, SLCO2B1*1/*1/ABCB1 3435CC, SLCO2B1*1/*1/ABCC2 -24CC, and ABCB1 1236CC/3435CC/ABCC2 -24CC compared to other polymorphic genotypes (p = 0.010, 0.033, 0.022, and 0.036, respectively), whereas there was no difference in the AUC0–24 between the SLCO1B1/1B3 plus ABCB1 and ABCC2 groups.The pharmacokinetic properties of S-fexofenadine are affected by a single polymorphism of SLCO2B1 in combination with several polymorphisms of ABCB1 C1236T, C3435T, and ABCC2 C-24T. However, the ABCG2 polymorphism was not associated with fexofenadine pharmacokinetics.These findings suggest that a combination of multiple transporters, including OATP, P-gp, and MRP2, reacts strongly to fexofenadine exposure in the small intestine and liver, resulting in different dispositions of both enantiomers.

Clinical pharmacokinetics of fexofenadine enantiomers

Drug-transporters play an important role in the disposition of clinical medicines. Although there are plural studies that have reported on the stereoselective pharmacokinetics related to cytochrome P450s, previous reports of the stereoselective pharmacokinetics related to drug-transporters including P-glycoprotein have been lacking. This article reviews the pharmacokinetic differences between fexofenadine enantiomers in humans and summarizes the previous reports that co-administration of P-glycoprotein inhibitors has altered the stereoselective pharmacokinetics of fexofenadine enantiomers. Both in vitro and in vivo studies have demonstrated that both itraconazole and verapamil are potent P-glycoprotein inhibitors. Therefore, by comparing the stereoselective pharmacokinetics of (R)- and (S)-fexofenadine with or without itraconazole and verapamil, the contribution of P-glycoprotein-mediated transport to fexofenadine stereoselective pharmacokinetics could be estimated. In our studies, the plasma concentrations of (R)-fexofenadine were greater than those of the corresponding (S)-enantiomer. Co-administration of itraconazole and/or verapamil significantly increased the AUC0 – 24 of both enantiomers; their influence on the P-glycoprotein-mediated transport of (S)-fexofenadine was greater than that of the (R)-enantiomer. However, because tmax and t1/2 were constant in both studies, the fexofenadine stereoselective pharmacokinetics appears to be due to P-glycoprotein efflux activity in the small intestine, which suggests that P-glycoprotein probably possesses the chiral discriminatory abilities.

Enantioselective disposition of fexofenadine with the P‐glycoprotein inhibitor verapamil

The aim was to compare possible effects of verapamil, as a P-glycoprotein (P-gp) inhibitor, on the pharmacokinetics of each fexofenadine enantiomer, as a P-gp substrate. Thirteen healthy Japanese volunteers (10 male and three female) were enrolled. In a randomized, two-phase, crossover design, verapamil was dosed 80 mg three times daily (with total daily doses of 240 mg) for 6 days, and on day 6, a single 120-mg dose of fexofenadine was administered along with an 80-mg dose of verapamil. Subsequently, fexofenadine was administered alone after a 2-week wash-out period. The plasma concentrations of fexofenadine enantiomers were measured up to 24 h after dosing. During the control phase, the mean AUC(0-infinity) of S(-)- and R(+)-fexofenadine was 700 ng h(-1) ml(-1)[95% confidence interval (CI) 577, 823] and 1202 ng h(-1) ml(-1) (95% CI 1007, 1396), respectively, with a significant difference (P < 0.001). Verapamil had a greater effect on the pharmacokinetic parameters of S(-)-fexofenadine compared with those of the R(+)-enantiomer, and increased AUC(0-infinity) of S(-)-fexofenadine and R(+)-fexofenadine by 3.5-fold (95% CI of differences 1.9, 5.1; P < 0.001) and by 2.2-fold (95% CI of differences 1.7, 3.0; P < 0.001), respectively. The R/S ratio for the AUC(0-infinity) was reduced from 1.76 to 1.32 (P < 0.001) by verapamil treatments. This study indicates that P-gp plays a key role in the stereoselectivity of fexofenadine pharmacokinetics, since the pharmacokinetics of fexofenadine enantiomers were altered by the P-gp inhibitor verapamil, and this effect was greater for S-fexofenadine compared with R-fexofenadine.

The different effects of itraconazole on the pharmacokinetics of fexofenadine enantiomers

Recently, we have shown that the plasma concentration of R-fexofenadine is greater than that of the S-enantiomer. Although itraconazole co-administration is known to increase the bioavailability of a racemic mixture of fexofenadine, little is known about the stereoselective inhibition of P-gp activity by itraconazole. This study indicates that the stereoselective pharmacokinetics of fexofenadine are due to P-gp-mediated transport and its stereoselectivity is altered by itraconazole, a an inhibitor of P-gp. The aim of this study was to determine the inhibitory effect of itraconazole, a P-glycoprotein (P-gp) inhibitor, on the stereoselective pharmacokinetics of fexofenadine. A two-way double-blind, placebo-controlled crossover study was performed with a 2-week washout period. Twelve healthy volunteers received either itraconazole 200 mg or matched placebo in a randomized fashion with a single oral dose of fexofenadine 60 mg simultaneously. The plasma concentrations and the amount of urinary excretion (Ae) of fexofenadine enantiomers were measured up to 24 h after dosing. After placebo administration, mean AUC(0,24 h) of S- and R-fexofenadine was 474 ng ml(-1) h (95% CI 311, 638) and 798 ng ml(-1) h (95% CI 497, 1101), respectively. Itraconazole affected the pharmacokinetic parameters of S-fexofenadine more, and increased AUC(0,24 h) of S-fexofenadine and R-fexofenadine by 4.0-fold (95% CI of differences 2.8, 5.3; P < 0.001) and by 3.1-fold (95% CI of differences 2.2, 4.0; P = 0.014), respectively, and Ae(0,24 h) of S-fexofenadine and R-fexofenadine by 3.6-fold (95% CI of differences 2.6, 4.5; P < 0.001) and by 2.9-fold (95% CI of differences 2.1, 3.8; P < 0.001), respectively. Additionally, the R : S ratio for AUC(0,24 h) and Ae(0,24 h) were significantly reduced in the itraconazole phase, while t(max), t(1/2) and renal clearance were constant during the study. This study indicates that the stereoselective pharmacokinetics of fexofenadine are due to P-gp-mediated transport and its stereoselectivity is altered by itraconazole, a P-gp inhibitor. However, further study will be needed because the different affinities of the two enantiomers for P-gp have not been supported by in vitro studies.

Pharmacokinetics of fexofenadine enantiomers in healthy subjects

Fexofenadine, a substrate of P-glycoprotein and an organic anion transporter polypeptide, is commonly used to assess P-glycoprotein activity in vivo. The purpose of this study was to elucidate the pharmacokinetics of each fexofenadine enantiomer. After a single oral dose of racemic fexofenadine (60 mg), the plasma and urine concentrations of fexofenadine enantiomers were measured over the course of 24 h in six healthy subjects. The mean plasma concentration of R(+)-fexofenadine was higher than that of S(-)-fexofenadine. The area under the plasma concentration-time curve (AUC(0-infinity)) and the maximum plasma concentration (C(max)) of R(+)-fexofenadine were significantly greater than those of the S(-)-enantiomer (P = 0.0018 and 0.0028, respectively). The R/S ratios of AUC and C(max) of fexofenadine were 1.75 and 1.63, respectively. The oral clearance and renal clearance of S(-)-fexofenadine were significantly greater than that of R(+)-fexofenadine (P = 0.0074 and 0.0036). On the other hand, the stereoselective metabolism of fexofenadine using recombinant CYP3A4 was investigated; however, fexofenadine enantiomers were not metabolized by CYP3A4. Fexofenadine is transported by both P-glycoprotein and OATP and is not metabolized by intestinal CYP3A. Our findings suggest that the affinity of P-glycoprotein for S(-)-fexofenadine is greater than its affinity for the R(+)-enantiomer. Thus, P-glycoprotein is likely to have chiral discriminatory abilities.

Determination of fexofenadine enantiomers in human plasma with high-performance liquid chromatography

A simple and sensitive high-performance liquid chromatography (HPLC) method was developed as an assay for fexofenadine enantiomers in human plasma. Fexofenadine enantiomers were separated using a mobile phase of 0.5% KH 2PO 4–acetonitrile (65:35, v/v) on a Chiral CD-Ph column at a flow rate of 0.5 ml/min and measurement at 220 nm. Analysis required 400 μl of plasma and involved solid-phase extraction with an Oasis HLB cartridge, which gave recoveries for both enantiomers from 67.4 to 71.8%. The lower limit of quantification was 25 ng/ml for ( R)- and ( S)-fexofenadine. The linear range of this assay was between 25 and 625 ng/ml (regression line r 2 > 0.993). Inter- and intra-day coefficients of variation were less than 13.6% and accuracies were within 8.8% over the linear range for both analytes. This method can be applied effectively to measure fexofenadine enantiomer concentrations in clinical samples.