Stereochemical aspects of parachloroamphetamine metabolism: Rabbit liver microsomal metabolism of RS-, R(-)-, and S(+)-para-chloroamphetamine

With the aid of a chiral derivatizing reagent and a sensitive and specific nitrogen-phosphorus gas Chromatographic assay, metabolism of para-chloroamphetamine (PCA) enantiomers has been studied following incubation of racemic (RS)-, R(?) and S(+)-PCA with rabbit liver microsomal preparations. Significant metabolism of racemic PCA and the individual enantiomers was observed following incubation in rabbit liver microsomal preparations. Metabolism required viable microsomes, NADPH and molecular oxygen, and the rate of metabolism increased following pretreatment with phenobarbital. Incubation of racemic PCA resulted in more rapid metabolism of the S(+) enantiomer than of the R(?) enantiomer. When the enantiomers were incubated individually, each enantiomer was metabolized more rapidly than when incubated as part of a racemic mixture, and the R(?) enantiomer was metabolized more rapidly than the S(+) enantiomer.     

Predicting Nonlinear Pharmacokinetics of Omeprazole Enantiomers and Racemic Drug Using Physiologically Based Pharmacokinetic Modeling and Simulation: Application to Predict Drug/Genetic Interactions

Purpose

The objective of this study is to develop a physiologically-based pharmacokinetic (PBPK) model for each omeprazole enantiomer that accounts for nonlinear PK of the two enantiomers as well as omeprazole racemic drug.

Methods

By integrating in vitro, in silico and human PK data, we first developed PBPK models for each enantiomer. Simulation of racemic omeprazole PK was accomplished by combining enantiomer models that allow mutual drug interactions to occur.

Results

The established PBPK models for the first time satisfactorily predicted the nonlinear PK of esomeprazole, R-omeprazole and the racemic drug. The modeling exercises revealed that the strong time-dependent inhibition of CYP2C19 by esomeprazole greatly altered the R-omeprazole PK following administration of racemic omeprazole as in contrast to R-omeprazole given alone. When PBPK models incorporated both autoinhibition of each enantiomer and mutual interactions, the ratios between predicted and observed AUC following single and multiple dosing of omeprazole were 0.97 and 0.94, respectively.

Conclusions

PBPK models of omeprazole enantiomers and racemic drug were developed. These models can be utilized to assess CYP2C19-mediated drug and genetic interaction potential for omeprazole and esomeprazole.     

Relationship Among Physicochemical Properties,Skin Permeability,and Topical Activity of the Racemic Compound and Pure Enantiomers of a New Antifungal

The topical antifungal Sch-39304 is a racemic compound comprised of two enantiomers, Sch-42427 and Sch-42426, only one of which (Sch-42427) is pharmacologically active. The pure enantiomers have a lower melting point and, therefore, a higher solubility than the racemic compound. Because of these differences in physicochemical properties, the concentration of the pure enantiomers in vehicles and in the skin was predicted to be an order of magnitude higher than the racemic compound. It was hoped that the pharmacological activity would also be higher. By measuring the flux of the chiral forms through human cadaver skin, the expected differences in skin solubility were confirmed. However, only a minimal difference between racemate and active enantiomer was observed in the lesion scores using a guinea pig dermatophyte model. By fitting the data to the E _max pharmacodynamic model, it is demonstrated that the maximum effect occurs at a concentration lower than the saturated concentration of the less soluble racemic compound. The data illustrate that the efficacy of topically active compounds may not be linearly related to drug concentration in either the vehicle or the skin.     

Pharmacokinetics of Ibuprofen Enantiomers in Humans Following Oral Administration of Tablets with Different Absorption Rates

Ibuprofen (IB) is a racemic drug and is administered as such. While activity is due mainly to the S enantiomer, pharmacokinetic interpretations, as well as criteria to assess the bioequivalence of IB formulations, are based on measurements of the total (S + R) drug concentrations. IB enantiomers possess different disposition properties mainly as a result of R-to-S isomeric bioinversion. Inversion is maximal during the absorption phase, suggesting, perhaps, involvement of a presystemic process. This concept was evaluated in healthy subjects by crossover administration of four IB tablets having different absorption rates. The plasma concentrations of the individual isomers were measured using a stereospecific gas chromatographic assay. Differences among the products were insignificant with respect to the extent to the absorption. The S:R concentration ratios rose for 4 to 6 hr and then remained relatively unchanged. This observation was consistent with equal terminal t _1/2 values for the enantiomers. There were significant differences between the peak times (T _max) of the products. The S:R ratios of the concentrations at T _max of S and AUC also differed; significant positive correlations were found between T _max and the S:R ratios of C _max. Thus the extent of R-to-S inversion, and hence the potency of a racemic dose of IB, may be absorption rate dependent.     

Pharmacokinetics of ibuprofen enantiomers after single and repeated doses in man.

The pharmacokinetic parameters of ibuprofen enantiomers after a single 600 mg dose and repeated 3 x 400 mg doses of Nurofen were determined in 12 healthy volunteers. Terminal half-lives were similar for both enantiomers, but plasma levels of S-ibuprofen were higher than those of R-ibuprofen, due to the chiral inversion and differences in distribution and metabolism. Comparison of maximal concentrations and areas under the concentration vs time curves between the first and last doses for each enantiomer indicated linear pharmacokinetics with no time-dependency. A large inter-individual variability in the ratio of S- to R-ibuprofen average concentrations at steady-state was observed (mean +/- SD 1.89 +/- 0.89) and probably accounts for the known lack of correlation between racemic ibuprofen concentrations and therapeutic efficacy.     

Rationale and conditions for the requirement of chiral bioanalytical methods in bioequivalence studies

Purpose

The aim of the present work was to assess the need for chiral bioanalytical methods in bioequivalence studies.

Methods

The samples from a bioequivalence study of two ibuprofen 2% oral suspensions that had shown bioequivalence for AUC and C_max, but not for t_max (medians of 2.0 and 0.75 h) with a non-chiral method were assayed with a chiral method to investigate whether there was an actual difference in the rate of absorption within the limits of C_max and AUC bioequivalence.

Results

The non-chiral method and the sum of concentrations of both enantiomers obtained with the chiral method gave a similar outcome (90% CI C_max non-chiral: 82.77–96.09, sum of enantiomers: 82.19–98.23; 90% CI AUC_t non-chiral: 107.23–115.49, sum of enantiomers: 105.73–121.35). However, the chiral method showed differences in AUC and C_max that resulted in non-bioequivalence for the individual enantiomers (90% CI C_max S-ibuprofen: 76.05–91.36, R-ibuprofen: 87.84–113.05; 90% CI AUC_t S-ibuprofen: 96.67–105.86, R-ibuprofen: 118.86–142.24). The differences in the pharmacokinetics of each enantiomer, and thus in the enantiomer concentration ratio, were dependent on the rate of absorption.

Conclusions

Due to the fact that in bioequivalence studies the rate of absorption of the new product is unknown, chiral bioanalytical methods should be employed for chiral drugs, such as ibuprofen, whose enantiomers exhibit different pharmacodynamic characteristics and whose enantiomer concentration ratio might be modified by the rate of absorption, irrespective of whether the eutomer is the minor enantiomer or the similarity of the pharmacokinetics of the enantiomers at a given rate of absorption.     

Enantiomeric Separation of Dioxopromethazine and its Stereoselective Pharmacokinetics in Rats by HPLC-MS/MS

Dioxopromethazine (DPZ) is a popular phenothiazine antihistamine that is widely used as a racemic drug in clinical to cure respiratory illness. In our work, a reliable, specific, and rapid enantioselective HPLC-MS/MS method has been established and fully validated for the quantification of R- and S-DPZ in rat plasma. After plasma alkalization (with 1 M Na₂CO₃), DPZ enantiomers and diphenhydramine (IS) were extracted using ethyl acetate. Completely separation of R- and S-DPZ (Rs = 2.8) within 12 min was implemented on Chiralpak AGP column (100 × 4.0 mm i.d., 5 μm) employing ammonium acetate (10 mM; pH 4.5) - methanol (90:10, v/v) as mobile phase. Themultiple reaction monitoring (MRM) mode was used for the detection of DPZ enantiomers and IS. The transitions of m/z 317.2 → 86.1 and 256.2 → 167.1 werechosen for monitoring DPZ enantiomers and IS, respectively. Good linearity (r² > 0.995) was achieved for each DPZ enantiomer over the linear ranges of 1.00 - 80.00 ng/mL, with the lower limit of quantitation (LLOQ) of 1.00 ng/mL. The intra-day and inter-day precisions (RSDs,%) were below 12.3%, and accuracies (REs,%) were in the scope of-10.5% to 6.6%, which were within the admissible criteria. The validated bioanalytical approach was applied to the stereoselective pharmacokinetic (PK) research of DPZ in rat plasma for the first time. It was found that significant differences (p < 0.05) exist between the main PK parameters of R- and S-DPZ, indicating the pharmacokinetic behaviors of DPZ enantiomers in rats were stereoselective. The chiral inversion of the enantiomers did not occur during the assay.     

Pharmacokinetics:Pharmacokinetic Differences Between Lansoprazole Enantiomers in Rats

Because limited information is available about potential differences between the pharmacokinetics and pharmacodynamics of the enantiomers of lansoprazole, the enantioselective pharmacokinetics of the compound have been investigated in rats. There was a noticeable difference between the serum levels of the enantiomers of lansoprazole and of their metabolites, 5-hydroxylansoprazole enantiomers, after oral administration of the racemate (50 mg kg^?1) to rats. C_max (maximum serum concentration) and AUC (area under the serum concentration-time curve) for (+)-lansoprazole were 5–6 times greater than those for (—)-lansoprazole, whereas for (+)-5-hydroxylansoprazole both values were significantly smaller than those for the (—) enantiomer. CL_tot/F values (where CL_tot is total clearance and F is the fraction of the dose absorbed) for (+)-lansoprazole were significantly smaller than those for the (—) enantiomer. There was no significant difference between the absorption rate constants of the lansoprazole enantiomers in the in-situ absorption study. The in-vitro protein-binding study showed that binding of (+)-lansoprazole to rat serum proteins was significantly greater than for the (—) enantiomer. The in-vitro metabolic study showed that the mean metabolic ratio (45.9%) for (—)-lansoprazole was significantly greater than that (19.8%) for the (+) enantiomer in rat liver microsomes at 5.6 μM lansoprazole. These results show that the enantioselective disposition of lansoprazole could be a consequence of the enantioselectivity of plasma-protein binding and the hepatic metabolism of the enantiomers.     

Stereoselective disposition of proton pump inhibitors

It is estimated that about half of all therapeutic agents are chiral, but most of these drugs are administered in the form of the racemic mixture, i.e. a 50/50 mixture of its enantiomers. However, chirality is one of the main features of biology, and many of the processes essential for life are stereoselective, implying that two enantiomers may work differently from each other in a physiological environment. Thus, receptors or metabolizing enzymes would recognize one of the ligand enantiomers in favour of the other. With one exception, all presently marketed proton pump inhibitors (PPIs)--omeprazole, lansoprazole, pantoprazole and rabeprazole--used for the treatment of gastric acid-related diseases are racemic mixtures. The exception is esomeprazole, the S-enantiomer of omeprazole, which is the only PPI developed as a single enantiomer drug. The development of esomeprazole (an alkaline salt thereof, e.g. magnesium or sodium) was based on unique metabolic properties that clearly differentiated esomeprazole from omeprazole, the racemate. At comparable doses, these properties led to several clinical advantages, for example higher bioavailability in the majority of patients, i.e. the extensive metabolizers (EMs; 97% in Caucasian and 80-85% in Asian populations), lower exposure in poor metabolizers (PMs; 3% in Caucasian and 15-20% in Asian populations) and lower interindividual variation. For the other, i.e. racemic, PPIs there are some data available on the characteristics of the individual enantiomers, and we have therefore undertaken to analyse the current literature with the purpose of evaluating the potential benefits of developing single enantiomer drugs from lansoprazole, pantoprazole and rabeprazole. For lansoprazole, the plasma concentrations of the S-enantiomer are lower than those of the R-enantiomer in both EMs and PMs, and, consequently, the variability in the population or between EMs and PMs is not likely to decrease with either of the lansoprazole enantiomers. Furthermore, plasma protein binding differs between the two lansoprazole enantiomers, in that the amount of the free S-enantiomer is two-fold higher than that of the R-enantiomer. This will counteract the difference seen in total plasma concentrations of the enantiomers. Also, studies using expressed human cytochrome P450 isoenzymes show that the metabolism of one enantiomer is significantly affected by the presence of the other, which is likely to result in different pharmacokinetics when administering a single enantiomer. For pantoprazole, there is a negligible difference in plasma concentrations between the two enantiomers in EMs, while the difference is substantial in PMs. The difference in AUC between PMs and EMs would decrease to some extent, but in the majority of the population the variability and efficacy would not be altered with a single enantiomer of pantoprazole. The metabolism of the enantiomers of rabeprazole displays stereoselectivity comparable to that of lansoprazole, i.e. the exposure of the R-enantiomer is higher than that of the S-enantiomer in EMs as well as in PMs, which, by analogy to lansoprazole, makes them less suitable for development of a single enantiomer drug. Furthermore, the chiral stability of the rabeprazole enantiomers may be an issue because of significant degradation of rabeprazole to its sulfide analogue, which is subject to non-stereoselective metabolic regeneration of a mixture of the two enantiomers. In conclusion, in contrast to esomeprazole, the S-enantiomer of omeprazole, minimal if any clinical advantages would be expected in developing any of the enantiomers of lansoprazole, pantoprazole, or rabeprazole as compared with their racemates.     

Drug disposition in three dimensions: an update on stereoselectivity in pharmacokinetics

Many marketed drugs are chiral and are administered as the racemate, a 50:50 combination of two enantiomers. Pharmacodynamic and pharmacokinetic differences between enantiomers are well documented. Because of enantioselectivity in pharmacokinetics, results of in vitro pharmacodynamic studies involving enantiomers may differ from those in vivo where pharmacokinetic processes will proceed. With respect to pharmacokinetics, disparate plasma concentration vs time curves of enantiomers may result from the pharmacokinetic processes proceeding at different rates for the two enantiomers. At their foundation, pharmacokinetic processes may be enantioselective at the levels of drug absorption, distribution, metabolism and excretion. In some circumstances, one enantiomer can be chemically or biochemically inverted to its antipode in a unidirectional or bidirectional manner. Genetic consideration such as polymorphic drug metabolism and gender, and patient factors such as age, disease state and concomitant drug intake can all play a role in determining the relative plasma concentrations of the enantiomers of a racemic drug. The use of a nonstereoselective assay method for a racemic compound can lead to difficulties in interpretation of data from, for example, bioequivalence or dose/concentration vs effect assessments. In this review data from a number of representative studies involving pharmacokinetics of chiral drugs are presented and discussed.     

Stereoselective pharmacokinetic analysis and antiepileptic activity of N-2-hydroxypropyl valpromide, a central nervous system--active chiral valproylamide

The purpose of this study was to evaluate the anticonvulsant activity and pharmacokinetics (PK) of a novel chiral CNS-active 2-hydroxypropyl valpromide (HP-VPD), a derivative of valproic acid (VPA). The individual enantiomers, R, S, and racemic (R,S)-HP-VPD were synthesized and evaluated for their pharmacokinetics and pharmacodynamics in a stereoselective manner. A stereoselective gas chromatography (GC) assay for simultaneous quantification of HP-VPD enantiomers in plasma and urine was developed and used to investigate the pharmacokinetics of HP-VPD in dogs. Pharmacodynamic analysis in rats showed that (S)-HP-VPD was 2.5 times more potent as an anticonvulsant in the maximal electroshock seizure (MES) test than its enantiomer and approximately 10 times more potent than VPA. No significant differences were observed in major PK parameters (clearance, volume of distribution, and half-life) between S and (R)-HP-VPD, and this suggested that pharmacodynamic differences could be attributed to the intrinsic pharmacodynamics of each enantiomer rather than to a preferable pharmacokinetic profile. The pharmacokinetic (metabolic) analysis showed that the fraction metabolized to HP-VPD-glucuronide ranged from 5% to 7% and no biotransformation of HP-VPD to VPA and 2-ketopropyl valpromide was observed. This is the first report of significant stereoselectivity in the anticonvulsant activity of a valproylamide with a chiral carbon situated on the alkyl chain of the amine moiety.     

Effect of dimethicone (polysilane gel) on the stereoselective pharmacokinetics of ketoprofen

Objective: Since dimethicone may be employed to improve gastrointestinal tolerability of non steroidal anti-inflammatory drugs (NSAIDs), we studied its influence on the pharmacokinetics of ketoprofen in subjects receiving a single oral dose of racemic ketoprofen. Patients and methods: In a cross-over experimental design, 12 healthy fasting volunteers were given a single oral dose (100 mg) of racemic ketoprofen, administered with or without dimethicone. The kinetic parameters measured were area under the concentration (AUC), maximum peak plasma concentration (C_max), time to reach peak concentration (t_max), elimination half-life (t_1/2), mean residence time (MRT) and urinary excretion for R and S enantiomers. Results: Dimethicone reduced the peak concentration of both R and S ketoprofen by about 10% (P < 0.05) and also induced a slight but non-significant increase in the mean time to achieve peak concentration. However, this treatment had no significant effect on the bioavailability and the elimination of R and S enantiomers, as shown by AUC, t_1/2 and MRT values. The absorption patterns were equivalent for both ketoprofen isomers, since plasma pharmacokinetic parameters were similar. Nevertheless, the urinary recovery was significantly lower for R ketoprofen than for its antipode. The administration of dimethicone did not alter this stereoselectivity. Conclusion: The administration of dimethicone to alleviate the epigastralgic effects related to NSAIDs does not affect the efficacy of the treatment. Dimethicone did not significantly alter the bioavailability of ketoprofen, chosen as an example of an NSAID, especially that of the pharmacologically active S enantiomer. Received: 5 August 1997 / Accepted in revised form: 7 March 1998     

The effect of experimental hyperlipidemia on the stereoselective tissue distribution, lipoprotein association and microsomal metabolism of (+/-)-halofantrine

The effect of hyperlipidemia on the biodistribution of (+/-)-halofantrine (HF) was studied in rats. Plasma, adipose, and highly perfused tissues heart, lung, liver, kidney, spleen and brain were harvested for up to 48 h after dosing animals with 2 mg/kg (+/-)-HF intravenously by tail vein. Stereospecific HPLC was used to measure HF and desbutyl-HF (DHF) enantiomer concentrations. Plasma concentrations of both HF enantiomers in hyperlipidemic (HL) exceeded those in normolipidemic (NL) rats by 11- to 15-fold. Significant increases in AUC of both HF enantiomers were noted in HL spleen tissue whereas decreases were seen in HL lung and fat. In rest of the tissues either decreases or no changes were noted in HL. The concentrations of DHF were very low in NL and HL plasma but were much higher in all highly perfused tissues. Both HF and DHF enantiomers shifted from lipoprotein deficient fraction to triglyceride-rich fractions in HL plasma following in vitro incubation of the respective racemic compounds. Compared to NL, no significant differences were noted in HF metabolism to DHF in HL liver microsomes. It would appear that both reduced plasma unbound fraction and lipoprotein associated directed uptake of lipoprotein-bound drug by tissues play roles in enantiomer biodistribution.     

Stereospecific Distribution of Methylphenidate Enantiomers in Rat Brain: Specific Binding to Dopamine Reuptake Sites

To investigate the stereoselective distribution of methylphenidate (MPD) enantiomers in rats, the concentrations of each enantiomer were determined in plasma and brain regions (cerebellum, striatum, basal forebrain, brain stem, and cortex) after iv administration of racemic MPD and its individual enantiomers. The concentrations of MPD enantiomers in each brain region reached pseudo-steady state within 10 min after iv administration of racemic MPD (2 mg/kg dose). The influx clearances for MPD calculated from K _Papp values in each brain region were not significantly different between MPD enantiomers and between the five brain regions. The mean K _Papp values for (+ )-MPD in the striatum at 120 and 240 min after administration of racemic MPD were 10.1 and 10.5, respectively, and these values at each time were significantly larger than the K _Papp values (7.5 and 7.0, respectively) for the (–)-isomer (P < 0.01). The K _Papp value for (+ )-MPD in the striatum decreased by coadministration of mazindol as an inhibition of both dopamine and norepinephrine reuptake, but it was not changed by desipramine as a norepinephrine reuptake inhibitor. These results suggest that ( + )-MPD was bound specifically to the dopamine reuptake site in the striatum.     

The relationship between the pharmacokinetics of ibuprofen enantiomers and the dose of racemic ibuprofen in humans

Ibuprofen is a chiral drug which is used clinically as a racemate. The pharmacological properties of ibuprofen reside almost exclusively with the S(+)-enantiomer. However, a portion of R(-)-ibuprofen is metabolically inverted to its pharmacologically active, mirror-image form. To investigate the influence of increasing dose of racemic ibuprofen on the pharmacokinetics of its individual enantiomers, four healthy male volunteers were given racemic ibuprofen (200, 400, 800, and 1200 mg), orally, on four occasions. The study was conducted using a balanced cross-over design. The extent of absorption of ibuprofen, as assessed by the total urinary recovery of ibuprofen and its metabolites, was extensive and independent of the administered dose. At all four doses, the area under the total and unbound plasma concentration-time curves (AUC and AUCu, respectively), and the unbound fraction in plasma, were significantly greater for the S(+)-enantiomer. With increasing ibuprofen dose, there was a less than proportional increase in the AUC of each enantiomer, while the AUCu for both enantiomers increased in direct proportion to the administered dose. The time-averaged unbound fraction of each enantiomer increased significantly with increasing dose, which caused the non-linearity between AUC and dose. It was predicted that the metabolic intrinsic clearance of each enantiomer, and the fraction of R(-)-ibuprofen which was metabolically inverted to S(+)-ibuprofen, was independent of the administered dose.     

Assay and disposition of carvedilol enantiomers in humans and monkeys: evidence of stereoselective presystemic metabolism

Carvedilol is a new beta-blocking agent with vasodilating activities, which is a racemic mixture of R(+)- and S(-)-enantiomers. Since the two enantiomers differ in pharmacological properties, it is necessary to individually measure their plasma concentrations in order to evaluate the pharmacological effects of racemic carvedilol after oral administration. In this study, a sensitive, stereospecific high-performance liquid chromatographic assay was used to determine the plasma concentration of each enantiomer. The assay involves the diastereomeric derivatization of racemic carvedilol with 2,3,4,6-tetra-O-acetyl-beta-D-glucopyranosyl isothiocyanate as a chiral reagent. After oral administration of racemic carvedilol to humans, the mean Cmax and AUC infinity values for R(+)-enantiomer were 2.6 and 2.8 times greater, respectively, than those for the more active S(-)-enantiomer. Similarly, in monkeys, the respective R:S enantiomer ratios for Cmax and AUC infinity were 1.5 and 1.2. The difference in AUCoral between these enantiomers is ascribed to the greater intrinsic clearance of S(-)-enantiomer than that of the R(+)-enantiomer in the liver, and to a lower plasma protein binding of the S(-)-enantiomer.     

The enantiomers of the teratogenic thalidomide analogue EM 12

The plasma pharmacokinetics of the enantiomers of 2-(2,6-dioxopiperidine-3-yl)-phthalimidine (EM 12) and the racemic mixture of this substance were investigated inCallithrix jacchus, a thalidomide-sensitive primate. Single doses of 5 mg/kg body wt were administered orally or intraperitoneally. Maximum plasma concentrations were reached 1 h after administration of the enantiomers, and 3 h after application of the racemate. The mean plasma elimination half-life was in the range of 5 h for the enantiomers, as well as for the racemic mixture, although there was a tendency toward slower elimination and higher plasma AUC values of the S-enantiomer: thus, after administration of the (>99%) pure enantiomers, the plasma AUC value of the administered S-enantiomer was found to be more than one-third higher than that of the administered R-enantiomer. Racemisation of the R- and the S-form of EM 12 occurred bothin vitro (phosphate buffer, pH 7.4, 37° C) andin vivo. The maximum plasma concentrations of the antipodes produced via chiral inversion were between 13% and 21%; the plasma AUC values of the resulting antipodes were between 24% and 30% of the corresponding values of total EM 12. The plasma pharmacokinetic data, including the extent of the chiral inversion obtained after p.o. and i.p. application of the substances, were in the same range. The results indicate that both enantiomers racemise with appreciable rates; this may be expected to complicate the interpretation of studies designed to evaluate stereoselective differences with respect to teratological activities of EM 12 and related substances such as thalidomide.Abbreviations EM 12 2-(2,6-dioxopiperidine-3-yl)-phthalimidine,3-(1,3-dihydro-1-oxo-2H-isoindol-2-yl)-2,6-dioxo-piperidine - S-EM 12 S-(–) enantiomer of EM 12 - R-EM 12 R-(+) enantiomer of EM 12     

Stereoselective pharmacokinetics of BOF-4272 racemate after oral administration to rats and dogs

The stereoselective pharmacokinetics of BOF-4272 enantiomers in rats and dogs was investigated by simultaneously measuring concentrations in arterial, portal, and venous plasma, the liver, and the kidney at 2 h after the oral administration of the racemic drug. The concentrations of BOF-4272 enantiomers were measured using high-performance liquid chromatography. The concentrations of the S(-) enantiomer in arterial, portal, and venous plasma were higher than those of the R(+) enantiomer in rats, but the opposite was found in dogs. In rats, absorption from the intestinal tract into the portal system was almost the same for the two enantiomers, whereas the hepatic uptake of the R(+) enantiomer was greater than that of the S(-) enantiomer. In dogs, absorption from the intestinal tract into the portal system was greater for the R(+) enantiomer than for the S(-) enantiomer, whereas hepatic uptake was comparable for the two enantiomers. The stereoselectivity of the renal uptake of BOF-4272 enantiomers had little effect on the stereoselectivity of enantiomers in the systemic circulation in both rats and dogs. The stereoselectivity in the systemic circulation of BOF-4272 enantiomers is therefore related to hepatic uptake in rats, and to absorption from the intestinal tract into the portal system in dogs.     

Stereoselective Passage of Mefloquine Through the Blood-Brain Barrier in the Rat

The pharmacokinetics of the enantiomers of mefloquine were studied in the rat after administration of a racemic mixture and of the separate enantiomers (+)-mefloquine and (–)-mefloquine. When 50 mg kg^?1 racemic mixture was administered orally for 22 days, plasma concentrations of the (+) enantiomer were 2–3 times higher than those of the (–) enantiomer whereas the opposite was true in every part of the brain (cerebellum, cortex, hippocampus, hypothalamus and striatum). Different concentrations of mefloquine were found in the different regions of the brain; the lowest concentrations of (±)-mefloquine (270 nmol g^?1) were in the cerebellum and the highest (1100 nmol g^?1) in the hippocampus. The main metabolite, carboxymefloquine, was detected in plasma but not in the brain. The results indicate that mefloquine crosses the blood-brain barrier stereoselectively.