Identification of the cytochrome P450 enzymes involved in the metabolism of cisapride: in vitro studies of potential co-medication interactions.

Cisapride is a prokinetic drug that is widely used to facilitate gastrointestinal tract motility. Structurally, cisapride is a substituted piperidinyl benzamide that interacts with 5-hydroxytryptamine-4 receptors and which is largely without central depressant or antidopaminergic side-effects. The aims of this study were to investigate the metabolism of cisapride in human liver microsomes and to determine which cytochrome P-450 (CYP) isoenzyme(s) are involved in cisapride biotransformation. Additionally, the effects of various drugs on the metabolism of cisapride were investigated. The major in vitro metabolite of cisapride was formed by oxidative N-dealkylation at the piperidine nitrogen, leading to the production of norcisapride. By using competitive inhibition data, correlation studies and heterologous expression systems, it was demonstrated that CYP3A4 was the major CYP involved. CYP2A6 also contributed to the metabolism of cisapride, albeit to a much lesser extent. The mean apparent K(m) against cisapride was 8.6+/-3.5 microM (n = 3). The peak plasma levels of cisapride under normal clinical practice are approximately 0.17 microM; therefore it is unlikely that cisapride would inhibit the metabolism of co-administered drugs. In this in vitro study the inhibitory effects of 44 drugs were tested for any effect on cisapride biotransformation. In conclusion, 34 of the drugs are unlikely to have a clinically relevant interaction; however, the antidepressant nefazodone, the macrolide antibiotic troleandomycin, the HIV-1 protease inhibitors ritonavir and indinavir and the calcium channel blocker mibefradil inhibited the metabolism of cisapride and these interactions are likely to be of clinical relevance. Furthermore, the antimycotics ketoconazole, miconazole, hydroxy-itraconazole, itraconazole and fluconazole, when administered orally or intravenously, would inhibit cisapride metabolism.

Pharmacokinetics of lubeluzole (Prosynap) after single intravenous doses in healthy subjects.

The single-dose pharmacokinetics of lubeluzole were investigated in 2 single-blind, placebo-controlled, dose-escalation studies in healthy male subjects. In the first study, 6 subjects received an intravenous infusion of 2.5, 5, and 10 mg lubeluzole. In the second study, a 15 mg dose of lubeluzole was administered to 6 subjects, of whom 5 also received 20 mg and 2 also 25 mg lubeluzole. Following the infusion, plasma lubeluzole concentrations decayed biphasically, with a mean distribution half-life (t1/2alpha) of 30 to 65 minutes and a mean terminal half-life (t1/2beta) of 15 to 24 hours. The results of the 2 studies indicate that lubeluzole exhibits linear kinetics over the dose range tested in healthy male subjects.

Population analysis of the non linear red blood cell partitioning and the concentration-effect relationship of draflazine following various infusion rates.

AIMS: To investigate the impact of the specific red blood cell binding on the pharmacokinetics and pharmacodynamics of the nucleoside transport inhibitor draflazine after i.v. administration at various infusion rates. It was also aimed to relate the red blood cell (RBC) occupancy of draflazine to the ex vivo measured adenosine breakdown inhibition (ABI). METHODS: Draflazine was administered to healthy volunteers as a 15-min i.v. infusion of 0.25, 0.5, 1, 1.5 and 2.5 mg immediately followed by an infusion of the same dose over 1 h. Plasma and whole blood concentrations were measured up to 120 h post dose, and were related to the ex vivo measured ABI, serving as a pharmacodynamic endpoint. The capacity-limited specific binding of draflazine to the nucleoside transporter located on the erythrocytes was evaluated by a population approach. RESULTS: The estimate of the population parameter typical value (%CV) of the binding constant Kd and the maximal specific binding capacity (Bmax) was 0.385 (3.5) ng ml-1 plasma and 158 (2.1) ng ml-1 RBC, respectively. The non-specific binding was low. The specific binding to the erythrocytes was a source of non-linearity in the pharmacokinetics of draflazine. The total plasma clearance of draflazine slightly decreased with increasing doses, whereas the total clearance in whole blood increased with increasing doses. The sigmoidal Emax equation was used to relate the plasma and whole blood concentration of draflazine to the ex vivo determined ABI. In plasma, typical values (%CV) of Emax, IC50 and Hill factor were 81.4 (1.9)%, 3.76 (9.3) ng ml-1 and 1.06 (3.4), respectively. The relationship in whole blood was much steeper with population parameter typical values (%CV) of Emax, IC50 and Hill factor of 88.2 (2.0)%, 65.7 (2.8) ng ml-1 and 4.47 (5.5), respectively. The RBC occupancy of draflazine did not coincide with the ex vivo measured ABI. The observed relationship between RBC occupancy and ABI was not directly proportional but similar for all studied infusion schemes. CONCLUSIONS: The findings of this study show that the occupancy of the nucleoside transporter by draflazine should be at least 90% in order to inhibit substantially adenosine breakdown in vivo. On the basis of these findings it is suggested that a 15 min infusion of 1 mg draflazine followed by an infusion of 1 mg h-1 could be appropriate in patients undergoing a coronary artery bypass grafting.

Population analysis of the non-linear red blood cell partitioning of draflazine following various infusion durations.

OBJECTIVE: The pharmacokinetics and non-linear red blood cell partitioning of the nucleoside transport inhibitor draflazine were investigated in 19 healthy male and female subjects (age range 22-55 years) after a 15-min i.v. infusion of 1 mg, immediately followed by infusions of variable rates (0.25, 0.5 and 1 mg.h-1) and variable duration (2-24 h). METHODS: The parameters describing the capacity-limited specific binding of draflazine to the nucleoside transporters located on erythrocytes were determined by NONMEM analysis. The red blood cell nucleoside transporter occupancy of draflazine (RBC occupancy) was evaluated as a pharmacodynamic endpoint. RESULTS: The population typical value for the dissociation constant Kd (%CV) was 0.648 (12) ng.ml-1 plasma, expressing the very high affinity of draflazine for the erythrocytes. The typical value of the specific maximal binding capacity Bmax (%CV) was 155 (2) ng.ml-1 RBC. The interindividual variability (%CV) was moderate for Kd (38.9%) and low for Bmax (7.8%). As a consequence, the variability in RBC occupancy of draflazine was relatively low, allowing the justification of only one infusion scheme for all subjects. The specific binding of draflazine to the red blood cells was a source of non-linearity in draflazine pharmacokinetics. Steady-state plasma concentrations of draflazine virtually increased dose-proportionally and steady state was reached at about 18 h after the start of the continuous infusion. The t1/2 beta averaged 11.0-30.5 h and the mean CL from the plasma was 327 to 465 ml.min-1. The disposition of draflazine in whole blood was different from that in plasma. The mean t1/2 beta was 30.2 to 42.2 h and the blood CL averaged 17.4-35.6 ml.min-1. CONCLUSION: Although the pharmacokinetics of draflazine were non-linear, the data of the present study demonstrate that draflazine might be administered as a continuous infusion over a longer time period (e.g., 24 h). During a 15-min i.v. infusion of 1 mg, followed by an infusion of 1 mg.h-1, the RBC occupancy of draflazine was 96% or more. As the favored RBC occupancy should be almost complete, this dose regimen could be justified in patients.

The implications of non-linear red blood cell partitioning for the pharmacokinetics and pharmacodynamics of the nucleoside transport inhibitor draflazine.

1. Draflazine, a nucleoside transport inhibitor, was administered as a 15 min i.v. infusion of 2.5 mg to eight healthy male subjects. Plasma and whole blood concentrations were measured up to 32 h post-dose, and were related to adenosine breakdown inhibition (ABI) measured ex vivo, which served as a pharmacodynamic endpoint. 2. The red blood cell/plasma distribution of draflazine was non-linear and characterized as a capacity-limited specific binding to the nucleoside transporter on the red blood cells. The binding (dissociation) constant Kd was 0.87 ng ml-1 plasma and the maximal specific binding capacity (Bmax) was 164 ng ml-1 RBC, which corresponds to about 14,000 specific binding sites per erythrocyte. Non-specific binding amounted to less than 15% of the total binding. 3. The pharmacokinetics of draflazine in blood were determined in each subject and characterized by a two-compartment pharmacokinetic model. The pharmacokinetic parameters (mean +/- s.d.) were: clearance 22.0 +/- 8.0 ml mm-1, volume of distribution at steady-state 39.8 +/- 4.7 l and terminal half-life 24.0 +/- 9.4 h. Concentrations in plasma were much lower, and could only be determined accurately in pooled plasma samples with a red blood cell binding assay. The pharmacokinetic parameters in pooled plasma were: clearance 551 ml min-1, volume of distribution at steady-state 349 l and terminal half-life 10.7 h. 4. A non-linear relationship was observed between the plasma or blood concentration of draflazine and the ABI determined ex vivo. This relationship was characterized by the sigmoidal Emax pharmacodynamic model. Based on concentrations in pooled plasma, values of the pharmacodynamic parameters were Emax 100%, IC50 10.5 ng ml-1 and Hill factor 0.9. When using whole blood concentrations, the relationship was much steeper with values (mean +/- s.d.) Emax 92.4 +/- 5.6%, IC50 76.0 +/- 15.3 ng ml-1 and Hill factor 3.5 +/- 0.9. 5. Binding to the nucleoside transporter on red blood cells is an important determinant of the pharmacokinetics of draflazine and a high degree of occupancy of the transporter by draflazine is required to inhibit adenosine breakdown ex vivo. It is suggested that red blood cell nucleoside transporter occupancy may serve as a useful pharmacodynamic endpoint in dose ranging studies with draflazine.

Effect of food on the pharmacokinetics of a new hydroxypropyl-beta-cyclodextrin formulation of itraconazole.

STUDY OBJECTIVE: To compare the pharmacokinetics of a single 100-mg oral dose of itraconazole administered as 10 ml of a 10-mg/ml itraconazole solution in hydroxypropyl-beta-cyclodextrin under fasting versus postprandial conditions. DESIGN: Open-label, two-way, randomized, crossover study. SETTING: Janssen Research Foundation, Belgium. PATIENTS: Twelve healthy volunteers. INTERVENTIONS: Blood samples were obtained for pharmacokinetic analyses immediately before dosing and at regular intervals up to 96 hours after each dose. Blood and urine samples were obtained for hematologic, biochemical, and urinary safety analyses at baseline and at the end of the study. MEASUREMENTS AND MAIN RESULTS: The mean peak plasma concentrations of both itraconazole and its active metabolite hydroxy-itraconazole were significantly higher under fasting conditions than under postprandial conditions. The mean times to peak concentration for both the parent compound and its metabolite were significantly shorter under fasting than under nonfasting conditions. The mean areas under the curve (AUC0-infinity and AUC0-24 hrs) were also significantly higher under fasting than under postprandial conditions. CONCLUSIONS: Our findings suggest that the higher bioavailability of this new formulation of itraconazole may be of benefit in seriously ill patients who are not able to ingest adequate quantities of food. The fact that the solution was also well tolerated and was not associated with clinically significant changes in any laboratory value further underscores the potential utility of this dosing form.

Location of the hydroxyl functions in hydroxylated metabolites of nebivolol in different animal species and human subjects as determined by on-line high-performance liquid chromatography-diode-array detection.

Nebivolol hydrochloride (R067555), is a new antihypertensive drug. Aromatic and alicyclic hydroxylation at the benzopyran ring systems of nebivolol are important metabolic pathways. Generally, NMR is used to unambiguously assign the sites of hydroxylation. Because of the low dose rates and the extensive metabolism of nebivolol in the different species, NMR identification is not always possible, and therefore another spectroscopic technique was searched for to address this problem. UV-chromophore absorption is affected by the kind and arrangement of adjacent atoms and groups (auxochromes). The effect of these auxochromes (e.g. -NH2, -NR2, -SH, -OH, -OR and halogens) can be strongly influenced by the pH. This paper proves that HPLC at high pH combined with on-line diode-array detection is an excellent technique for the location of the hydroxyl functions in hydroxylated metabolites of nebivolol. With this technique it is possible to differentiate between glucuronidation at the automatic and aliphatic or alicyclic hydroxyl functions.

Linearity of pharmacokinetics and model estimation of sufentanil.

BACKGROUND: The pharmacokinetic profiles of sufentanil available in the literature are conflicting because of methodologic differences. Length of sampling and assay sensitivity are key factors involved in accurately estimating the volumes of distribution, clearances, and elimination phase. The unit disposition function of increasing doses of sufentanil were investigated and the influence of dose administered on the linearity of pharmacokinetics was assessed. METHODS: The pharmacokinetics of sufentanil were investigated in 23 patients, aged 14-68 yr, scheduled for surgery with postoperative ventilation. After induction of anesthesia, sufentanil was administered as a short infusion (10-20 min) in doses ranging from 250 micrograms to 1,500 micrograms. Frequent arterial blood samples were gathered during and at the end of infusion, then at specific intervals up to 48 h after infusion. Plasma concentrations of sufentanil were measured by radioimmunoassay (limit of sensitivity 0.02 ng.ml-1). The data were analyzed with the standard two-stage, naive pooled-data and the mixed effect pharmacokinetic approaches. RESULTS: The pharmacokinetics of sufentanil were adequately described by a linear three-compartmental mamillary model with the following parameters, expressed as log mean values with 95% confidence intervals: the central volume of distribution = 14.3 l (13.1-15.41), the rapidly equilibrating volume = 63.1 l (61.9-64.3 l), the slowly equilibrating volume = 261.6 l (260.2-262.9 l), the steady-state distribution volume = 339 l (335-343 l), metabolic clearance = 0.92 l.min-1 (0.84-1.05 l.min-1), rapid distribution clearance = 1.55 l.min-1 (1.34-2.14 l.min-1), slow distribution clearance = 0.33 l.min-1 (0.27-0.49 l.min-1), and elimination half-life = 769 min (690-1011 min). No relation to age, weight, or lean body mass was found for any of the parameters. CONCLUSIONS: Sufentanil pharmacokinetics were linear within the dose range studied. Drug detection up to 24 h after dosing was necessary to define the terminal elimination phase. The metabolic clearance approached liver blood flow and a large volume of distribution was identified, consistent with the long terminal elimination half-life. Simulations predicted that plasma sufentanil steady-state concentrations would rapidly decline after termination of an infusion despite the long half-lives.

Influence of age, renal and liver impairment on the pharmacokinetics of risperidone in man.

The pharmacokinetics of the antipsychotic agent risperidone were investigated in healthy young and elderly subjects, cirrhotic patients and patients with moderate and severe renal insufficiency. In a comparative trial, a single oral 1-mg dose was administered to fasting subjects. Plasma and urine concentrations of the parent compound risperidone and the active moiety (i.e. risperidone plus 9-hydroxy-risperidone) were measured by radioimmunoassays. No or only small changes in plasma protein binding were observed in hepatic and renal disease, whereas the protein binding was not influenced by aging. The inter-individual variability in plasma concentrations of the active moiety was much less than the variability in plasma concentrations of risperidone. Three out of six subjects, behaving like poor metabolizers, were on medication (thiethylperazine, amitriptyline, metoprolol) that may inhibit risperidone metabolism by CYP2D6 (debrisoquine 4-hydroxylase). The pharmacokinetics of risperidone in elderly and cirrhotic patients were comparable to those in young subjects, whereas total oral clearance was reduced in renal disease patients. The elimination rate and clearance of 9-hydroxy-risperidone was reduced in elderly and renal disease patients because of a diminished creatinine clearance. The CL(oral) of the active moiety, which is primarily 9-hydroxy-risperidone, was reduced by about 30% in the elderly and by about 50% in renal disease patients. In addition, the t1/2 of the active moiety was prolonged (19 h in young subjects versus about 25 h in elderly and renal disease patients). Based upon the pharmacokinetics of the active moiety, a dose reduction and a cautious dose titration is advised in the elderly and in patients with renal disease. In cirrhotic patients, the single-dose pharmacokinetics were comparable to those in healthy young subjects.

The pharmacokinetic properties of topical levocabastine. A review.

The linear and predictable pharmacokinetic properties of the histamine H1-receptor antagonist levocabastine make it particularly suitable for intranasal or ocular treatment of allergic rhinoconjunctivitis. Peak plasma concentrations (Cmax) occur within 1 to 2 hours of administration of single doses of levocabastine nasal spray and eye drops (0.2mg and 0.04mg, respectively). Drug absorption is incomplete after intranasal and ocular administration, with systemic availability ranging from 60 to 80% for levocabastine nasal spray and from 30 to 60% for the eye drops. However, as the amount of levocabastine applied intranasally and ocularly is small, the levocabastine plasma concentrations achieved are extremely low, with Cmax values in the ranges 1.4 to 2.2 micrograms/L and 0.26 to 0.29 micrograms/L for intranasal and ocular administration, respectively. Pharmacokinetic-pharmacodynamic modelling has indicated that the clinical benefits of levocabastine are predominantly mediated through local antihistaminic effects, although some systemic activity may contribute to the therapeutic efficacy of levocabastine nasal spray during long term use. Levocabastine undergoes minimal hepatic metabolism, i.e. ester glucuronidation, and is predominantly cleared by the kidneys. Approximately 70% of parent drug is recovered unchanged in the urine. Plasma protein binding is approximately 55% and the potential for drug interactions involving binding site displacement is negligible. Furthermore, the pharmacokinetics of this agent do not appear to be influenced by either age or gender. Levocabastine nasal spray and eye drops may thus be considered suitable for the treatment of allergic rhinoconjunctivitis in a wide patient population.

Reduction of the prodrug loperamide oxide to its active drug loperamide in the gut of rats, dogs, and humans.

Loperamide oxide (LOPOX) is a prodrug of loperamide (LOP). The reduction of LOPOX to LOP was investigated to provide a pharmacokinetic basis for the pharmacodynamics and improved side effect profile of the prodrug. Reduction of LOPOX was studied in vitro in gut contents, gut flora, intestinal cells, and hepatocytes. In vivo pharmacokinetics and metabolism of LOPOX and LOP were compared in the dog. LOPOX could be efficiently reduced in the gut contents of rats, dogs, and humans, with the most extensive reduction found in cecal contents. Reduction was diminished to 13% of the anaerobic LOPOX reductase activity in the presence of oxygen and to 2.5% of the original activity by heat treatment of the contents. In human ileal effluents, LOPOX reductase activity was similar in oxygen and heat sensitivity. In the rat, the cecum contained on average 89.2% of the total activity in the contents of the upper part of the intestine. In the dog, there was a gradual increase in LOPOX reductase activity from the proximal small intestine toward the cecum. In germ-free rats, the cecum contained < 1% of the activity of the small intestine. Isolated intestinal microflora of rat and dog was able to reduce LOPOX to LOP under anaerobic conditions, indicating that the microflora was primarily involved in the reduction. In its absence (i.e. in germ-free rats), reduction could still be conducted by other unknown components of the gut contents. In isolated intestinal cells, the initial rate of drug uptake was approximately 3-10 times faster for LOP than for LOPOX.(ABSTRACT TRUNCATED AT 250 WORDS)

Gastrointestinal distribution of the prodrug loperamide oxide and its active drug loperamide in the dog.

Loperamide oxide is a prodrug of the effective antidiarrheal loperamide. Administration of this prodrug improves efficacy and tolerability. For better understanding of these effects, the absorption and gastrointestinal distribution of loperamide oxide and of its active drug loperamide were studied. Beagle dogs received a single oral dose of loperamide oxide or loperamide at 0.16 mg/kg. Plasma, gastrointestinal contents and tissues, and some other organs were obtained. Concentrations were determined by specific radioimmunoassays. Loperamide oxide was gradually converted to loperamide in the gastrointestinal tract. After administration of the prodrug, the systemic absorption of the active drug was lower and more delayed than after administration of loperamide itself. As a consequence, more loperamide was available in the contents and the mucosa of the gut, in particular in the lower part of the small intestine and in the large intestine. The higher levels of loperamide in mucosa may cause more pronounced and longer lasting antisecretory effects after administration of loperamide oxide. The results of this study are in line with the hypothesis that loperamide oxide is a site-specific prodrug that acts as a chemically designed controlled-release form of loperamide keeping a higher amount of the active drug for a longer time at the site of action in the gut wall.

The pharmacokinetics of risperidone in humans: a summary.

Risperidone is rapidly and completely absorbed after oral administration; less than 1% is excreted unchanged in the feces. The principal metabolite was found to be 9-hydroxyrisperidone. Hydroxylation of risperidone is subject to the same genetic polymorphism as debrisoquine and dextromethorphan. In poor metabolizers the half-life of risperidone was about 19 hours compared with about 3 hours in extensive metabolizers. However, becuase the pharmacology of 9-hydroxyrisperidone is very similar to that of risperidone, the half-life for the "active fraction" (risperidone +9-hydroxyrisperidone) was found to be approximately 20 hours in extensive and poor metabolizers. We found that risperidone exhibited linear elimination kinetics and that steady state was reached within 1 day for risperidone and within 5 days for the active fraction.

Plasma protein binding of risperidone and its distribution in blood.

The plasma protein binding of the new antipsychotic risperidone and of its active metabolite 9-hydroxy-risperidone was studied in vitro by equilibrium dialysis. Risperidone was 90.0% bound in human plasma, 88.2% in rat plasma and 91.7% in dog plasma. The protein binding of 9-hydroxy-risperidone was lower and averaged 77.4% in human plasma, 74.7% in rat plasma and 79.7% in dog plasma. In human plasma, the protein binding of risperidone was independent of the drug concentration up to 200 ng/ml. The binding of risperidone increased at higher pH values. Risperidone was bound to both albumin and alpha 1-acid glycoprotein. The plasma protein binding of risperidone and 9-hydroxy-risperidone in the elderly was not significantly different from that in young subjects. Plasma protein binding differences between patients with hepatic or renal impairment and healthy subjects were either not significant or rather small. The blood to plasma concentration ratio of risperidone averaged 0.67 in man, 0.51 in dogs and 0.78 in rats. Displacement interactions of risperidone and 9-hydroxy-risperidone with other drugs were minimal.

Assay methods for sufentanil in plasma. Radioimmunoassay versus gas chromatography-mass spectrometry.

BACKGROUND: The terminal pharmacokinetic parameters of sufentanil have, until now, been poorly characterized. This is probably because of the poor sensitivity or unreliability of the assay methods used. Radioimmunoassay (RIA) can be a very helpful assay method for sufentanil. However, before application to key pharmacokinetic studies, it requires adequate validation, e.g., by comparison with a method of proven sensitivity and specificity, such as gas chromatography-mass spectrometry (GC-MS). METHODS: Spiked control plasma samples and 135 plasma samples obtained from five patients receiving intravenous doses of 500 or 750 micrograms sufentanil, as a 10-20-min infusion, were analyzed by an improved, sensitive RIA and capillary GC-MS. RESULTS: Both techniques had comparable limits of quantitation (0.02 ng/ml). Between-day coefficients of variation in the 0.05-10-ng/ml concentration range were 8.5-10.5% for the RIA and less than 10% for the GC-MS method. The patient plasma concentrations determined by RIA (y) and GC-MS (x) showed a good agreement (y = 1.016x + 0.002) and a correlation coefficient of 0.97. CONCLUSIONS: The results demonstrate the validity of the improved RIA method for the determination of sufentanil plasma concentrations.

Regional brain distribution of risperidone and its active metabolite 9-hydroxy-risperidone in the rat.

Risperidone is a new benzisoxazole antipsychotic. 9-Hydroxy-risperidone is the major plasma metabolite of risperidone. The pharmacological properties of 9-hydroxy-risperidone were studied and appeared to be comparable to those of risperidone itself, both in respect of the profile of interactions with various neurotransmitters and its potency, activity, and onset and duration of action. The absorption, plasma levels and regional brain distribution of risperidone, metabolically formed 9-hydroxy-risperidone and total radioactivity were studied in the male Wistar rat after single subcutaneous administration of radiolabelled risperidone at 0.02 mg/kg. Concentrations were determined by HPLC separation, and off-line determination of the radioactivity with liquid scintillation counting. Risperidone was well absorbed. Maximum plasma concentrations were reached at 0.5-1 h after subcutaneous administration. Plasma concentrations of 9-hydroxy-risperidone were higher than those of risperidone from 2h after dosing. In plasma, the apparent elimination half-life of risperidone was 1.0 h, and mean residence times were 1.5 h for risperidone and 2.5 h for its 9-hydroxy metabolite. Plasma levels of the radioactivity increased dose proportionally between 0.02 and 1.3 mg/kg. Risperidone was rapidly distributed to brain tissues. The elimination of the radioactivity from the frontal cortex and striatum--brain regions with high concentrations of 5-HT2 or dopamine-D2 receptors--became more gradual with decreasing dose levels. After a subcutaneous dose of 0.02 mg/kg, the ED50 for central 5-HT2 antagonism in male rats, half-lives in frontal cortex and striatum were 3-4 h for risperidone, whereas mean residence times were 4-6 h for risperidone and about 12 h for 9-hydroxy-risperidone. These half-lives and mean residence times were 3-5 times longer than in plasma and in cerebellum, a region with very low concentrations of 5-HT2 and D2 receptors. Frontal cortex and striatum to plasma concentration ratios increased during the experiment. The distribution of 9-hydroxy-risperidone to the different brain regions, including frontal cortex and striatum, was more limited than that of risperidone itself. This indicated that 9-hydroxy-risperidone contributes to the in vivo activity of risperidone, but to a smaller extent than would be predicted from plasma levels. AUCs of both active compounds in frontal cortex and striatum were 10-18 times higher than those in cerebellum. No retention of metabolites other than 9-hydroxy-risperidone was observed in any of the brain regions investigated.

The metabolism and excretion of risperidone after oral administration in rats and dogs.

The metabolism and excretion of risperidone (RIS; 3-[2-[4-(6-fluoro-1,2-benzisoxazole-3-yl)-1-piperidinyl]ethyl]-6,7,8,9- tetrahydro-2-methyl-4H-pyrido[1,2-a]pyrimidin-4-one), a novel antipsychotic drug, were studied after single po administration of radiolabeled RIS to rats and dogs. In rats, the excretion of the radioactivity was very rapid. The predominant excretion in rat feces (78-82% of the dose) was related to an extensive biliary excretion of metabolites (72-79% of the dose), only a small part of which underwent enterohepatic circulation. In dogs, about 92% of the dose had been excreted after one week, and the fractions recovered in the urine and feces were comparable. Only a few percent of a po dose was excreted as unchanged RIS in rats as well as in dogs. Major metabolic pathways of RIS in rats and dogs were the same as those in humans. The main pathway was the hydroxylation at the alicyclic part of the 6,7,8,9-tetrahydro-2-methyl-4H-pyrido[1,2-a]pyrimidin-4-one moiety. The resulting 9-hydroxy-risperidone (9-OH-RIS) was the main metabolite in the excreta of dogs. In rats, the metabolism was more extensive, resulting in dihydroxy-RIS and hydroxy-keto-RIS, which were eliminated mainly via the bile. However, in male and in female rats, just as in dogs and humans, the active metabolite 9-OH-RIS was by far the main plasma metabolite. Other major metabolic pathways were the oxidative dealkylation at the piperidine nitrogen and the scission of the isoxazole in the benzisoxazole ring system. The latter pathway appeared to be effected primarily by the intestinal microflora.(ABSTRACT TRUNCATED AT 250 WORDS)

Pharmacokinetics of orally administered levocabastine in patients with renal insufficiency.

The effects of renal insufficiency and hemodialysis on the pharmacokinetics of orally administered levocabastine were studied in six nondialysis patients and in six patients undergoing regular hemodialysis. Levocabastine .5 mg, supplied as a solution, was administered orally to each patient 1 hour after breakfast. Compared with data in healthy volunteers, the oral absorption and disposition of levocabastine were impaired in patients with renal insufficiency. The time to reach peak plasma concentration was increased and the peak plasma concentration was decreased in the patients with renal insufficiency compared with healthy volunteers. Urinary excretion of the unchanged drug, which is the major elimination pathway of levocabastine, was reduced in the patients with renal insufficiency. The decreased urinary excretion most likely contributed to the prolonged half-life (from 36 hours to 95 hours) and increased area under the plasma concentration-time curve (+56%) in the patients with renal insufficiency as compared with the healthy volunteers. Although the 6-hour hemodialysis procedure starting 4 hours after dosing eliminated 10% of the oral dose, the terminal half-life and the total area under the plasma concentration-time curve did not differ significantly between the hemodialysis and the nonhemodialysis patients. In conclusion, the current study showed that the initial oral absorption of levocabastine is reduced and that levocabastine elimination is prolonged in patients with renal insufficiency.

Absorption, metabolism, and excretion of risperidone in humans.

The absorption, metabolism, and excretion of the novel antipsychotic risperidone was studied in three healthy male subjects. One week after a single oral dose of 1 mg [14C]risperidone, 70% of the administered radioactivity was recovered in the urine and 14% in the feces. Unchanged risperidone was mainly excreted in the urine and accounted for 30, 11, and 4% of the administered dose in the poor, intermediate, and extensive metabolizer of debrisoquine, respectively. Alicyclic hydroxylation at the 9-position of the tetrahydro-4H-pyrido[1,2-a]-pyrimidin-4-one moiety was the main metabolic pathway. The active metabolite 9-hydroxy-risperidone accounted for 8, 22, and 32% of the administered dose in the urine of the poor, intermediate, and extensive metabolizer, respectively. Oxidative N-dealkylation at the piperidine nitrogen, whether or not in combination with the 9-hydroxylation, accounted for 10-13% of the dose. In methanolic extracts of feces, risperidone, and benzisoxazole-opened risperidone and hydroxylated metabolites were detected. 9-Hydroxy-risperidone was by far the main plasma metabolite. The sum of risperidone and 9-hydroxy-risperidone accounted for the largest part of the plasma radioactivity in the three subjects. Although the debrisoquine-type genetic polymorphism plays a distinct role in the metabolism of risperidone, the pharmacokinetics of the active fraction (i.e. risperidone plus 9-hydroxy-risperidone) remained similar among the three subjects.

Discrepancies in bioassay and chromatography determinations explained by metabolism of itraconazole to hydroxyitraconazole: studies of interpatient variations in concentrations.

Pharmacologic studies of itraconazole (IZ), a triazole antifungal, indicated unexplained differences between bioassay and chromatographic determinations and large variations in steady-state blood concentrations. We show that concentrations of a hydroxylated metabolite, hydroxyitraconazole (HIZ), are approximately twofold higher than IZ over a range of concentrations. Though HIZ and IZ appear equipotent against selected pathogens, HIZ is two to three times more active against a commonly used bioassay fungus but minimally affects IZ activity. Hence, HIZ probably contributes importantly to the therapeutic activity attributed to IZ and contributes approximately four to six times the activity of IZ in bioassays, explaining discrepancies observed between assay methods.