Histamine H1 receptor antagonism by cetirizine in isolated guinea pig tissues: influence of receptor reserve and dissociation kinetics

We characterised histamine H(1) receptor antagonism by cetirizine and its enantiomers on isolated guinea pig ileum and trachea. Competitive or mixed (competitive and apparent noncompetitive) antagonism profiles were observed. The order of potency was: chlorpheniramine> or =mepyramine>levocetirizine>cetirizine> or =terfenadine>loratadine>dextrocetirizine. The inhibitory effects of cetirizine, levocetirizine, terfenadine and loratadine were slowly reversible compared to those of dextrocetirizine or mepyramine. Cetirizine and its enantiomers were inactive on L-type Ca(2+) channels. Reduction of the histamine H(1) receptor reserve by dibenamine in the ileum (100-fold higher than in the trachea) showed a gradual change from the competitive profile of dextrocetirizine and mepyramine to a mixed profile. The present results show that cetirizine and levocetirizine are selective competitive but slowly reversible histamine H(1) receptor antagonists. Their mixed antagonism profile observed in the trachea can be explained by the small receptor reserve present in this tissue compared to the ileum and their very slow dissociation rate from the histamine H(1) receptor.     

Compared pharmacological characteristics in humans of racemic cetirizine and levocetirizine, two histamine H1-receptor antagonists

The potent histamine H(1)-receptor antagonist cetirizine (Zyrtec) is a racemic mixture of levocetirizine (now available under the trademark Xyzal and dextrocetirizine. In this Commentary, we examine some biological properties of cetirizine and levocetirizine, namely enantioselectivity in pharmacological activity and pharmacokinetic properties, with emphasis on the possibility of racemization, the compared behavior of the two enantiomers, and the potential for interactions with other drugs. Recent data demonstrate that the antihistaminergic activity of the racemate is primarily due to levocetirizine. Levocetirizine is rapidly and extensively absorbed, poorly metabolized, and not subject to racemization. Its pharmacokinetic characteristics are comparable after administration alone or in the racemate. Its apparent volume of distribution is smaller than that of dextrocetirizine (0.41 L kg(-1) vs. 0.60 L kg(-1)). Moreover, the non-renal (mostly hepatic) clearance of levocetirizine is also significantly lower than that of dextrocetirizine (11.8 mL min(-1) vs. 29.2 mL min(-1)). Our conclusion is that levocetirizine is indeed the eutomer of cetirizine. The evidence reviewed here confirms preclinical findings and offers a rationale for the chiral switch from the racemate to levocetirizine.     

Physicochemical, pharmacological and pharmacokinetic properties of the zwitterionic antihistamines cetirizine and levocetirizine

Cetirizine, marketed as a racemic mixture containing both levocetirizine and dextrocetirizine, is a member of the second generation H(1) antihistamines clinically used for the treatment of symptoms associated with seasonal allergic rhinitis. Recently, its single R-enantiomer levocetirizine has been approved by the FDA as the newest antihistamine. Cetirizine is a piperazine derivative related to the first generation H(1) antagonist hydroxyzine, and is the major metabolite in the blood circulation after hydroxyzine administration in humans. The acid functionality of cetirizine in combination with one of the basic nitrogens of piperazine ring makes this compound a very unique zwitterion. The molecular structure of cetirizine allows its carboxylic group to interact with the basic nitrogen via folded conformers, therefore, it possesses relatively high lipophilicity at physiological pH (LogD=1.5). While both cetirizine and hydroxyzine possess high affinity at the H(1) receptor, the R-configured levocetirizine has much slower dissociation rate from the H(1) receptor than R-hydroxyzine, making it an insurmountable antagonist. In addition, the pharmacokinetics of cetirizine significantly differs from those of the basic and lipophilic hydroxyzine. For example, cetirizine has much lower CNS penetration than hydroxyzine, which may be explained by the zwitterionic structure of cetirizine and its P-glycoprotein activity. Cetirizine exhibits high intestinal absorption in humans and its oral bioavailability is estimated to be greater than 70%. Very importantly, cetirizine, especially levocetirizine, has a negligible interaction with the liver enzymes, and is mainly excreted in the urine as the parent despite its high plasma protein binding (88 approximately 96%). The recommended dose of levocetirizine is 5 mg once daily, while its pharmacokinetic half-life is about 7 h in humans. This review will focus on the physicochemical, pharmacological and pharmacokinetic properties of cetirizine and levocetirizine in comparison with those of hydroxyzine. The zwitterionic cetirizine displays distinct advantages over the basic hydroxyzine in several categories such as slow receptor dissociation rate, high selectivity, negligible liver enzyme interaction and low CNS penetration. Therefore, cetirizine, or its single isomer levocetirizine, might serve a good example for medicinal chemists to design zwitterionic drugs from a basic, acidic or neutral lead molecule for peripheral biological targets.     

Prediction of human oral pharmacokinetics using nonclinical data: examples involving four proprietary compounds

The oral pharmacokinetics (concentration-time profile) of four proprietary compounds in humans were predicted using the C(vss)-MRT method. The first step was to demonstrate superposition of intravenous (i.v.) pharmacokinetic profiles of preclinical species following mathematical transformation of their respective concentration-time curves using the corresponding C(vss) (where C(vss)=dose/Vss; Vss is the volume of distribution at steady state) and mean residence time (MRT) values. The resultant profiles were then back-transformed to estimate human i.v. plasma concentration-time profiles using human C(vss) and MRT values. Human C(vss) and MRT values were estimated from projected human Vss and CL values. Projection of CL was based on scaled (in vitro) metabolic clearance, simple allometry with and without various correction factors and the unbound fraction corrected intercept method. Vss values were estimated by allometric scaling with and without correction for interspecies differences in plasma protein binding. The predicted human i.v. profiles, in combination with the estimated mean absorption rate constants and bioavailability, were then used to simulate the oral pharmacokinetics in human using one- or multi-compartment kinetic models. Overall, with this approach, key oral pharmacokinetic parameters such as AUC, C(max), C(min) and oral plasma T((1/2)) were projected to be within two-fold of the actual values in humans.     

Effects of age and dose on the pharmacokinetics of ibuprofen in the rat.

The pharmacokinetics of ibuprofen after 2.5 and 25 mg/kg doses were examined in young adult (5 months) and senescent (24 months) male Fischer 344 rats. Plasma concentrations of ibuprofen were determined by HPLC and protein binding was measured by equilibrium dialysis. The cytochrome P-450-mediated metabolism of ibuprofen was investigated in vitro using microsomal protein from rat liver as the source of drug-metabolizing enzymes. Dose had a marked effect on the disposition of ibuprofen, with free plasma clearance (CLfree) decreasing 40% and apparent free steady-state volume of distribution (Vssfree) decreasing 58% as dose increased from 2.5 to 25 mg/kg. These changes reflected saturation of elimination pathways and tissue-binding sites. The binding of ibuprofen to plasma proteins was dependent on drug concentration. Unlike the parameters based on free ibuprofen concentrations, there were no significant changes in total plasma clearance (CL) or steady-state volume of distribution (Vss) due to the nonlinear protein binding. Aging also had a significant effect on ibuprofen pharmacokinetics. Decreases in CLfree and Vssfree of 42 and 51%, respectively, suggested a reduction in metabolic activity and binding of ibuprofen to tissue components in the aged rats. A decrease in plasma protein binding in the old rats was related to decreases in albumin concentration and the number of albumin binding sites. Thus, due to the greater free fraction of ibuprofen in the plasma of aged rats, CL increased significantly, whereas Vss remained unaffected by age when total plasma concentrations were examined. The metabolic capacity exhibited an age-related decline of 42%, whereas the affinity of the metabolic enzymes for ibuprofen was unaffected by age.     

Pharmacokinetics of a glycine site antagonist (gavestinel) following multiple dosing in patients with acute stroke

OBJECTIVE: The objective of this study was to characterize the pharmacokinetics of gavestinel in patients with acute stroke. METHODS: Gavestinel was administered as an 800-mg loading dose and followed by either 100-, 200-, or 400-mg maintenance doses given every 12 h for five doses. Blood and urine samples were collected for pharmacokinetic evaluation. The pharmacokinetics of gavestinel were determined using compartmental analysis. RESULTS: The mean clearance (CL) and central (Vc) and steady-state (Vss) volumes of distribution across the dose groups were 0.31-0.40 l x h(-1), 3.3-3.9 l, and 9.8-17 l, respectively. The mean terminal half-life ranged from 29 h to 56 h. Gavestinel was extensively bound to plasma protein (median percentage free <0.01). During gavestinel administration, some patients exhibited elevated levels of bilirubin, which may be the result of shared mechanisms of elimination (glucuronide conjugation and excretion in bile). CONCLUSIONS: This study characterized the pharmacokinetics of gavestinel following multiple doses in acute stroke patients and showed that the pharmacokinetics are similar for increasing maintenance doses. The high protein binding of gavestinel was confirmed in acute stroke patients. A pharmacokinetic interaction between gavestinel and bilirubin may contribute to the increase in bilirubin.     

Structure-pharmacokinetic relationships among the N1,N3-alkylxanthines in rats.

The pharmacokinetics of four N3-alkylxanthine and four N1-methyl-N3-alkylxanthine derivatives has been investigated in rats after intravenous administration of the individual alkylxanthines. The concentration of N1,N3-alkylxanthine in plasma and urine was determined by HPLC. A one-compartment model adequately described the plasma concentration time data. The steady-state volume of distribution (Vss) was calculated using model-independent methods. The relation between Vss and unbound drug fraction in plasma (fu) was significantly correlated (Vss = 0.844fu + 0.119; r = 0.999, P less than 0.01), indicating that the differences in fu among these xanthine derivatives is mainly responsible for differences in Vss. The decrease in Vss and increase in plasma protein binding with lipophilicity reflected a relatively constant tissue affinity. The total body clearance increased with lipophilicity with the exception of the first three lower congeners which were almost completely excreted unchanged in urine, mainly via active tubular secretion. Renal elimination was markedly reduced by the presence of a methyl group at the N1-position. Renal clearance decreased with increasing lipophilicity, due to increased tubular reabsorption whereas non-renal (hepatic) clearance increased with increasing lipophilicity.     

Retrospective population pharmacokinetics of levocetirizine in atopic children receiving cetirizine: the ETAC study

AIMS: To evaluate the population pharmacokinetics of levocetirizine in young children receiving long-term treatment with cetirizine. METHODS: Data were available from a randomized, double-blind, parallel group and placebo-controlled study of cetirizine in 343 young children between 12 and 24 months of age at entry, who were at high risk of developing asthma, but were not yet affected (ETAC study). Infants received oral drops of cetirizine at 0.25 mg kg(-1) twice daily for 18 months. Plasma concentration of the active enantiomer levocetirizine was determined in blood samples collected at months 3, 12 and 18 (1-3 samples per child). A one-compartment open model was fitted to the data using nonlinear mixed effects modelling (NONMEM). The influence of weight, age, gender, BSA and other covariates on CL/F and V/F was evaluated. RESULTS: CL/F increased linearly with weight by 0.044 l h(-1) kg(-1) over an intercept of 0.244 l h(-1), and V/F increased linearly with weight by 0.639 l kg(-1). Population estimates in children with weights of 8 and 20 kg were 0.60 and 1.13 l h(-1) for CL/F, and 5.1 and 12.8 l for V/F, respectively, with interpatient variabilities of 24.4% and 14.7%. Weight-normalized estimates of CL/F and V/F were higher than in adults. The estimated relative bioavailability was 0.28 in 12% of instances of suspected noncompliance. Levocetirizine pharmacokinetics were not influenced by severe allergy or aeroallergen sensitization. Results on the effects of concomitant medications or diseases were inconclusive due to limited positive cases. AUC(ss), calculated in compliant subjects using posterior estimates of the final model, was 1952 (1227-3319) microg l(-1) h (mean, min-max), a value similar to that in adults after intake of 5 mg oral solution (2036 (1414-2827) microg l(-1) h. CONCLUSIONS: The model suggests that administration of levocetirizine 0.125 mg kg(-1) twice daily in children 12-48 months of age or weighing 8-20 kg yields the same exposure as in adults taking the recommended dose of 5 mg once daily.     

Binding characteristics of cetirizine and levocetirizine to human H(1) histamine receptors: contribution of Lys(191) and Thr(194).

Competition experiments with [(3)H]mepyramine showed that cetirizine and its enantiomers, levocetirizine and (S)-cetirizine, bound with high affinity and stereoselectivity to human H(1) histamine receptors (K(i) values of 6, 3, and 100 nM, respectively). Cetirizine and levocetirizine were 600-fold more selective for H(1) receptors compared with a panel of receptors and channels. Binding results indicated that the interaction between cetirizine, its enantiomers, and histamine is compatible with a competitive behavior, in contrast with the noncompetitive profile of cetirizine and levocetirizine observed in isolated organs. Binding kinetics provided a suitable explanation for this observation, because levocetirizine dissociated from H(1) receptors with a half-time of 142 min; that of (S)-cetirizine was only 6 min, implying that the former could act as a pseudo-irreversible antagonist in functional studies. The carboxylic function of levocetirizine seemed responsible for its long dissociation time. Indeed, hydroxyl or methyl ester analogs dissociated more rapidly from H(1) receptors, with half-times of 31 min and 7 min, respectively. The importance of the carboxylic function of levocetirizine for the interaction with the H(1) receptor was further supported by the results from the mutation of Lys(191) to Ala(191). This mutation decreased the dissociation half-time of levocetirizine from 142 to 13 min and reduced its affinity from 3 to 12 nM, whereas the affinity and dissociation kinetics of hydroxyl and methyl ester analogs were hardly affected. The mutation of Thr(194) reduced the binding stereoselectivity by selectively enhancing the affinity of the distomer.     

Elucidation of Human Amphotericin B Pharmacokinetics: Identification of a New Potential Factor Affecting Interspecies Pharmacokinetic Scaling

Purpose. To elucidate the pharmacokinetics of amphotericin B in rats, mice and humans, and to perform interspecies scaling to humans using allometry. Methods. Plasma concentrations following intravenous bolus administration in rats, and mice were determined by HPLC. Human pharmacokinetic parameters elucidated from literature data were validated in a preliminary study involving a patient receiving daily infusion dose for 27 days. A critical literature review was conducted to identify appropriate pharmacokinetic parameter values in other species for interspecies scale-up. Interspecies allometric scale-up was performed across mice, rats, rabbits and dogs and the resulting predictions in humans were compared to observed values. Results. A triexponential decline in rat, mouse and human plasma concentrations were observed. No gender differences in rat pharmacokinetics were observed. In contrast to allometry, mouse CL was smaller (82 vs 116 ml/h/kg) and T_0.5 (33 vs 20 h) was longer compared to rat. In the preliminary human study, Cpeak and Cmin values remained relatively constant over the duration of therapy, and a CL, MRT, T_0.5, Vss and Vdarea of 26 ml/h/kg, 10 and 23 days, 6.2 and 20 L/kg, respectively, were estimated. The relative contributions of the terminal phase area in rat, mouse and human were 75%, 92% and 31%, respectively. Interspecies allometric scale-up predictions of human CL (41 ml/h/kg), CLu (467 ml/h/kg) and Vss (3.3 L/kg) were similar to reported values, whereas poor predictions of human Vuss (33 L/kg), Vdarea (4.1 L/kg) and T_0.5 (3 days) were obtained. Conclusions. Insignificant accumulation in humans inspite of the long terminal T_0.5 was rationalized to be due to the small terminal-phase area contribution. While human CL and Vss were sucessfully predicted in the interspecies scaling, poor predictions of human Vdarea and T_0.5 were obtained, which was attributed to disposition pattern differences between humans and other species, a potential new critical factor affecting interspecies scale-up.     

连翘酯苷A在大鼠体内的药动学及其血浆蛋白结合率研究

 目的：研究连翘酯苷A在大鼠体内的药动学及其血浆蛋白结合率。方法：大鼠按10 mg?kg-1静脉注射连翘酯苷A,不同时间点采集血样。采用高效液相色谱法(HPLC)测定其血药浓度,应用Topfit 2.0软件计算其主要药动学参数;采用超滤法研究连翘酯苷A的血浆蛋白结合率。结果：大鼠静脉注射连翘酯苷A后主要药动学参数为t1/2=(20.6±4.4) min,Ke=(0.034±0.006) min-1,Vd=(0.66±0.14) L,CL=(22.2±1.7) mL?min-1,MRT=(5.29±1.12) min,AUC0~100 min=(450.97±36.04) μg?min?mL-1,AUC0~∞=(453.22±36.37) μg?min?mL-1。连翘酯苷A在浓度为1,5和25 μg?mL-1时,大鼠平均血浆蛋白结合率分别为69.3%,67.2%和62.9%。结论：连翘酯苷A在大鼠体内符合二室开放模型,具有体内分布快、血药浓度下降迅速等特点。同时,血浆蛋白结合率结果表明,连翘酯苷A具有中等强度的血浆蛋白结合率。     

Brain distribution of cetirizine enantiomers: comparison of three different tissue-to-plasma partition coefficients: K(p), K(p,u), and K(p,uu).

The objective of this study was to compare the blood-brain barrier (BBB) transport and brain distribution of levo- (R-CZE) and dextrocetirizine (S-CZE). Microdialysis probes, calibrated using retrodialysis by drug, were placed into the frontal cortex and right jugular vein of eight guinea pigs. Racemic CZE (2.7 mg/kg) was administered as a 60-min i.v. infusion. Unbound and total concentrations of the enantiomers were measured in blood and brain with liquid chromatography-tandem mass spectrometry. The brain distribution of the CZE enantiomers were compared using the parameters K(p,) K(p,u,) K(p,uu), and V(u,br). K(p) compares total brain concentration to total plasma concentration, K(p,u) compensates for binding in plasma, whereas K(p,uu) also compensates for binding within the brain tissue and directly quantifies the transport across the BBB. V(u,br) describes binding within the brain. The stereoselective brain distribution indicated by the K(p) of 0.22 and 0.04 for S- and R-CZE, respectively, was caused by different binding to plasma proteins. The transport of the CZE enantiomers across the BBB was not stereoselective, since the K(p,uu) was 0.17 and 0.14 (N.S.) for S- and R-CZE, respectively. The K(p,uu) values show that the enantiomers are effluxed to a large extent across the BBB. The V(u,br) of approximately 2.5 ml/g brain was also similar for both the enantiomers, and the value indicates high binding to brain tissue. Thus, when determining stereoselectivity in brain distribution, it is important to study all factors governing this distribution, binding in blood and brain, and the BBB equilibrium.     

Pharmacokinetics of coagulation factors: clinical relevance for patients with haemophilia.

Haemophilia is a recessively inherited coagulation disorder, in which an X-chromosome mutation causes a deficiency of either coagulation factor VIII (FVIII) in haemophilia A, or factor IX (FIX) in haemophilia B. Intravenous administration of FVIII or FIX can be used to control a bleeding episode, to provide haemostasis during surgery or for long term prophylaxis of bleeding. In special cases, activated factor VII (FVIIa) may be used instead of FVIII or FIX. The aim of this work is to review the pharmacokinetics of FVIII, FIX and FVIIa and to give an outline of the use of pharmacokinetics to optimise the treatment of patients with haemophilia. The pharmacokinetics of FVIII are well characterised. The systemic clearance (CL) of FVIII is largely determined by the plasma level of von Willebrand factor (vWF), which protects FVIII from degradation. Typical average CL in patients with normal vWF levels is 3 ml/h/kg, with an apparent volume of distribution at steady state (Vss) that slightly exceeds the plasma volume of the patient, and the average elimination half-life (t1/2) is around 14 hours. There are still some discrepancies in the literature on the pharmacokinetics of FIX. The average CL of plasma-derived FIX seems to be 4 ml/h/kg, the Vss is 3 to 4 times the plasma volume and the elimination t1/2 often exceeds 30 hours. FVIIa has a much higher CL (average of 33 ml/h/kg), and a short terminal t1/2 (at 2 to 3 hours). The Vss is 2 to 3 times the plasma volume. Since the therapeutic levels of coagulation factors are well defined in most clinical situations, applied pharmacokinetics is an excellent tool to optimise therapy. Individual tailoring of administration in prophylaxis has been shown to considerably increase the cost effectiveness of the treatment. Dosage regimens for the treatment of bleeding episodes or for haemostasis during surgery are also designed using pharmacokinetic data, and the advantages of using a constant infusion instead of repeated bolus doses have been explored. The influence of antibodies (inhibitors) on the pharmacokinetics of FVIII and FIX is in part understood, and the doses of coagulation factor needed to treat a patient can tentatively be calculated from the antibody titre. In conclusion, therapeutic monitoring of coagulation factor levels and the use of clinical pharmacokinetics to aid therapy are well established in the treatment of patients with haemophilia.     

Absorption, distribution, metabolism and excretion of [14C]levocetirizine, the R enantiomer of cetirizine, in healthy volunteers

The main goal of the present study was to investigate the absorption and disposition of levocetirizine dihydrochloride, the R enantiomer of cetirizine dihydrochloride, following a single oral administration (5 mg) of the 14C-labelled compound in healthy volunteers. Configurational stability was also investigated. Levocetirizine was rapidly and extensively absorbed: 85.4% and 12.9% of the radioactive dose were recovered 168 h post-dose in urine and faeces, respectively. Levocetirizine and/or its metabolites were not, or only very poorly, associated with blood cells, as the blood-to-plasma ratio was 0.51 to 0.68. The mean apparent volume of distribution (Vz/F) was 26.9 1 (0.3 l/kg) indicating that the distribution of levocetirizine is restrictive. The protein binding of radiolabelled levocetirizine was 96.1% l h after administration. In vitro, at concentrations ranging from 0.2 microg/ml to 1 microg/ml, the protein binding was 94.8% to 95.0%. Levocetirizine is very poorly metabolised. The cumulative 48-h excretion as parent compound accounted for 85.8% of the oral dose, equivalent to 95% of the total radioactivity excreted at this time. At least 13 minor metabolites were detected in urine and represented 2.4% of the dose at 48 h. The metabolic pathways involved in levocetirizine metabolism are oxidation (hydroxylation, O-dealkylation, N-oxidation and N-dealkylation), glucuroconjugation, taurine conjugation and glutathione conjugation with formation of the mercapturic acids. There was no evidence of chiral inversion of levocetirizine in humans. This result is consistent with that obtained in preclinical studies.     

Prediction of clinical pharmacokinetic parameters of linezolid using animal data by allometric scaling: applicability for the development of novel oxazolidinones

1. Allometric scaling has previously been used as an effective tool for the prediction of human pharmacokinetic data. The pharmacokinetic data for linezolid, a novel oxazolidinone to treat Gram-positive pathogens, in mice, rats and dogs were subjected to simple allometric scaling. Generated allometric equations for parameters such as clearance (CL), volume of distribution (Vss) and elimination rate constant (K10) were used to predict human pharmacokinetic parameters including elimination half-lives. In addition, the human plasma concentration-time curve was simulated using a one-compartmental model. 2. Application of simple allometry (Y = aWb) for animal parameters such as CL, Vss, and K10 showed excellent allometric fit (r > or = 0.98). The allometric equations for CL, Vss, and K10 were -0.5465W(0.6595), -0.1369W(0.9246), and -0.4117W(-0.3139), respectively. The confidence in predictability of CL and Vss parameters was particularly high since the allometric exponents of CL and Vss almost approached the suggested values of 0.75 and 1.00, respectively. 3. Animal pharmacokinetic parameters generated in the present authors' laboratories for linezolid were in close agreement with reported literature values. The predicted human values for CL (4.68 l h(-1)), Vss (37.07 litres), and K10 (0.10 h(-1)) were within the range observed for linezolid in the literature (CL = 4-10.5 l h(-1); Vss = 21-53 litres; K10 = 0.09-0.3 h(-1)). The human half-life (t(1/2)) predicted using allometry (6.9 h) was similar to reported values in humans of 5 h. In summary, the retrospective analysis for linezolid suggests that allometric scaling can be used as a prospective tool for predicting human pharmacokinetic parameters of novel oxazolidinones.     

Pharmacokinetics and toxicity of idarubicin in the rat.

This study was designed to examine the pharmacokinetics and toxicity of idarubicin (IDA) in rats. In two groups of rats IDA was infused either into the V. iugularis interna or into the A. carotis communis, respectively. The venous plasma concentration of IDA and its primary metabolite idarubicinol (IDOL) were measured up to 48 hours by high-performance liquid chromatography (HPLC) with fluorescence detection. The weights of the rats and the levels of haemoglobin, leukocytes, and thrombocytes were recorded. The plasma concentration-time data were analysed, assuming a biexponential disposition curve, both by the traditional (two-stage) method and by population pharmacokinetic modelling. The basic pharmacokinetic parameters clearance (CL = 27.0 ml min(-1)), mean disposition residence time (MDRT = 519.2 min), and volume of distribution at steady state (Vss = 12.51) were estimated for IDA. The mean residence time (MRT) of the generated IDOL was 2982.5 min. No significant differences between pre- and postpulmonal injection were found in the pharmacokinetics and pharmacodynamics of IDA. The mean survival time of 13.3 days is attributed to a severe myelosuppression.     

Enantioseparation of cetirizine by chromatographic methods and discrimination by 1H‐NMR

Cetirizine is an antihistaminic drug used to prevent and treat allergic conditions. It is currently marketed as a racemate. The H1‐antagonist activity of cetirizine is primarily due to (R)‐levocetirizine. This has led to the introduction of (R)‐levocetirizine into clinical practice, and the chiral switching is expected to be more selective and safer. The present work represents three methods for the analysis and chiral discrimination of cetirizine. The first method was based on the enantioseparation of cetirizine on silica gel TLC plates using different chiral selectors as mobile phase additives. The mobile phase enabling successful resolution was acetonitrile‐water 17: 3, (v/v) containing 1 mM of chiral selector, namely hydroxypropyl‐β‐cyclodextrin, chondroitin sulphate or vancomycin hydrochloride. The second method was a validated high performance liquid chromatography (HPLC), based on stereoselective separation of cetirizine and quantitative determination of its eutomer (R)‐levocetirizine on a monolithic C18 column using hydroxypropyl‐β‐cyclodextrin as a chiral mobile phase additive. The resolved peaks of (R)‐levocetirizine and (S)‐dextrocetirizine were confirmed by further mass spectrometry. The third method used a ¹H‐NMR technique to characterize cetirizine and (R)‐levocetirizine. These methods are selective and accurate, and can be easily applied for chiral discrimination and determination of cetirizine in drug substance and drug product in quality control laboratory. Moreover, chiral purity testing of (R)‐levocetirizine can also be monitored by the chromatographic methods. Copyright © 2009 John Wiley & Sons, Ltd.     

Pharmacokinetics of gacyclidine enantiomers in plasma and spinal cord after single enantiomer administration in rats

The purpose of this study was to determine the pharmacokinetics of gacyclidine, a non-competitive NMDA antagonist, in plasma and spinal cord extracellular fluid (ECF) after IV administration of single enantiomers in rats. After implantation of microdialysis probes in spinal cord, concentrations in plasma and ECF dialysates were determined by a chiral GC/MS assay over 5 h after administration of either (+)-gacyclidine or (-)-gacyclidine (1.25 mg/kg). Plasma protein binding was estimated in vitro by equilibrium dialysis. Plasma concentrations decayed in parallel in a biphasic manner (t(1/2)alpha approximately 9 min; t(1/2)beta approximately 90 min) with no significant difference between the two enantiomers. Clearance of (+)-gacyclidine and (-)-gacyclidine (291 versus 275 ml/min per kg, respectively), volume of distribution (Vdbeta: 38 versus 40 l/kg), and protein binding (90 versus 89%) were not stereoselective. Both gacyclidine enantiomers were quantifiable in spinal cord ECF 10 min after drug administration and their concentrations remained stable over the duration of the experiment in spite of changing blood concentrations. Penetration of the two enantiomers in spinal cord ECF was similar although highly variable between animals. Exposure of spinal cord ECF was comparable for both enantiomers, and not correlated with plasma AUCs. This study showed the absence of any pharmacokinetic difference between the two enantiomers when administered individually, and no enantiomeric inversion. Both gacyclidine enantiomers penetrate rapidly and extensively into spinal cord ECF, and their distribution may involve an active transport system.     

Pharmacokinetics of ketoprofen in rats: effect of age and dose.

The effects of age and dose on the pharmacokinetics of ketoprofen were evaluated in young adult and senescent male Fischer 344 rats following intravenous administration of 2.5 and 10 mg kg-1. Plasma concentrations were measured by HPLC and free ketoprofen determined by equilibrium dialysis. The glucuronidation of ketoprofen was investigated in a preparation of rat liver microsomes and kinetic analysis of UDP-glucuronyltransferase was carried out by determining the initial rate of metabolic activity as a function of ketoprofen concentration. Mean plasma clearance CLfree and steady-state volume of distribution Vssfree calculated from unbound plasma ketoprofen concentrations were significantly lower in the aged rat, suggesting reduced metabolic activity and decreased ketoprofen binding to tissue components, respectively. Plasma protein binding demonstrated an age-dependent decline due to decreases in both albumin concentration and binding affinity. Thus, plasma clearance CL and steady-state volume of distribution Vss changes were insignificant when total plasma concentrations were examined, due to the greater free fraction of ketoprofen in the plasma of senescent rats. The maximal rate of ketoprofen glucuronidation by hepatic microsomes was reduced whereas the affinity of the metabolic enzymes for the compound was unaffected by age. Dose had a marked effect on the disposition of ketoprofen as well. Saturation of elimination pathways and tissue binding sites contributed to significant declines in CLfree and Vssfree with increasing dose. Likewise, concentration-dependent plasma protein binding occurred, reflecting saturation of albumin binding. Thus, changes in the pharmacokinetic parameters based on total drug concentrations were offset by the increase in the unbound fraction of ketoprofen.     

国产盐酸西替利嗪片的药代动力学研究

目的 :建立测定国产盐酸西替利嗪 (西可韦 )血药浓度的方法并进行人体药代动力学研究。方法 :采用反相高效液相色谱法 ,以盐酸普罗帕酮为内标 ;色谱柱 :WaterssymmetryC18 不锈钢柱 (3 9mm×150mm ,5μm) ;流动相 :乙腈 -0 02mol/L磷酸二氢钠 -三乙胺 (50∶50∶0 16 ,V/V) ,含十二烷基硫酸钠 (SDS)4 0mmol/L ;流速 :1 0ml/min ;检测波长 :229nm。测定11名健康男性志愿者单剂量口服西可韦片10mg 的血浆中药物浓度。结果 :线性范围为12 5～800ng/ml,最低检测限为5ng/ml,提取回收率>75 %。11名志愿者的血药浓度数据经3p87软件拟合 ,符合血管外给药二室模型 ,其主要药代动力学参数为 :Cmax=(429 00±108 80)ng/ml,Tmax= (0 91±0 40)h ,K10= (0 18±0 04)/h ,以梯形法计算的AUC0～36= (3312 72±682 39)ng/(ml·h)。结论 :本方法结果准确 ,灵敏度高 ,能满足人体药代动力学研究的需要 ;西可韦主要药代动力学参数与国内、外文献报道一致 ,可广泛应用于临床