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.

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.

Induction potential of fluconazole toward drug-metabolizing enzymes in rats.

The induction of drug-metabolizing enzymes in rat liver was studied after subchronic administration of the new triazole antifungal agent fluconazole. The administered doses were 10, 40, and 160 mg/kg per day for 7 days. Fluconazole behaved as a high-magnitude inducer and significantly increased cytochrome P-450 concentrations already at 10 mg/kg (+42%). Cytochrome P-450 induction by fluconazole was dose dependent and reached a value of 302% of the control value at the dose of 160 mg/kg. The induction effects on cytochrome P-450 were also reflected in the drug-metabolizing enzyme activities in hepatic microsomes of pretreated rats. Fluconazole (160 mg/kg per day) preferentially induced the demethylase activities of N,N-dimethylaniline and p-nitroanisole to 258 and 281% of the control values, respectively. The detoxification enzyme UDP-glucuronosyltransferase was significantly lowered by fluconazole at the highest dose. A possible link between the induction potential and the pharmacokinetic properties of triazole antifungal agents is discussed.

Is the metabolism of alfentanil subject to debrisoquine polymorphism? A study using human liver microsomes.

The present study was designed to investigate whether the metabolism of the opiate analgesic alfentanil in humans is subject to the debrisoquine 4-hydroxylation polymorphism. The role of a specific cytochrome P-450 form, debrisoquine 4-hydroxylase, in the metabolism of alfentanil was investigated by competitive inhibition experiments over the concentration range 4-100 microM. Alfentanil was incubated with human liver microsomes in the presence of an NADPH-generating system. Alfentanil and its major metabolites were quantified in the incubates by reversed phase high-performance liquid chromatography (HPLC). Alfentanil was rapidly metabolized, yielding noralfentanil as the main metabolite. Kinetically, alfentanil metabolism occurred monophasically and the kinetic parameters were 22.8 microM for Km app and 3.86 nmol alfentanil metabolized min-1.mg protein-1 for Vm app. Debrisoquine was a weak, noncompetitive inhibitor of alfentanil metabolism and of the formation of its major metabolites, with Ki values between 2.00 and 3.21 mM. It can be concluded that alfentanil is not metabolized in vitro by the human cytochrome P-450 form involved in debrisoquine 4-hydroxylation; therefore, the in vivo disposition of the drug is most likely not affected by deficiency of this enzyme.

Mass spectral investigation of the metabolites of lorcainide in man.

[3H] Lorcainide hydrochloride was administered orally to healthy male volunteers. About 97% of the total radioactivity was excreted in the urine and faeces within four days of its administration. The metabolites were purified by adsorption chromatography, liquid-liquid extraction, thin layer chromatography or by gas chromatography-mass spectrometry after silylation of the samples. When there was a sufficient amount available, the samples were submitted to a nuclear magnetic resonance analysis. The results were confirmed by comparison of spectral data obtained from the reference compounds. The major metabolites of lorcainide were formed by aromatic hydroxylation, O-methylation and oxidative N-dealkylation. The urinary phenolic metabolites were present both as free aglycons and conjugates.

Plasma protein binding and distribution of fentanyl, sufentanil, alfentanil and lofentanil in blood.

The in vitro plasma protein binding and distribution in blood of fentanyl and three analogues were studied in rats, dogs and healthy volunteers. In human plasma, 84.4% of fentanyl was bound, 92.5% of sufentanil, 92.1% of alfentanil and 93.6% of lofentanil. Plasma protein binding of the four analgesics was independent of their concentration over the whole therapeutic range. Plasma protein binding of alfentanil was much less pH dependent than that of the three other analgesics. Attention was drawn to the possible contribution of the "acute phase' protein alpha 1-acid glycoprotein (alpha 1-AGP), of lipoproteins and of blood cells to the binding of fentanyl and its analogues in blood.

In-vitro metabolism of etomidate by rat liver fractions.

(R)-(+)-etomidate and (S)-(-)-etomidate were found to be metabolized in-vitro by various rat liver homogenization fractions: the 16,000 g supernatant fraction caused a more intensive metabolic breakdown than the microsomal fraction; the 100,000 g supernatant fraction was only slightly active. The metabolism was somewhat more rapid and more extensive for the (R)-(+)-etomidate than for the (S)-(-)-isomer. For both isomers, a dose-dependence was observed: the smaller the substrate concentration, the smaller the relative amount of unmetabolized drug, and the more the rate of metabolic breakdown after a certain incubation time slowed down. Only minor qualitative differences between the metabolic pathways of the two isomers were observed. The main metabolic pathway for the in-vitro metabolism was the hydrolysis of the ethyl ester. Decarboxylation and oxidative N-dealkylation were also observed.

The plasma protein binding and distribution of etomidate in dog, rat and human blood.

The interactions of etomidate and its major metabolite (R 28 141) with plasma proteins were studied by equilibrium dialysis with a multiple cell system. A 4% human serum albumin solution was able to bind 78.5% of the etomidate, and 60.5% of R 25 141, whereas a 1.5% human gamma globulin solution bound etomidate for not more than 3% and did not bind R 28 141 at all. The association constants and free binding energies for the binding of etomidate and R 28 141 to human serum albumin were determined. Plasma protein binding of etomidate was 75.4% in the dog and 76.5% in man; in rat plasma 79.5% of the radioactivity was bound to the plasma proteins, however the etomidate was partly hydrolyzed, even in the presence of sodium fluoride. In the rat 29.7% was distributed to the blood cells, 55.9% bound to plasma proteins and 14.4% was present in plasma water; in the dog the distribution percentages were 42.1%, 43.7% and 14.2% respectively, and in man 37.7%, 47.6% and 14.7% respectively. The major metabolite of etomidate was distributed for 26.3% to the human blood cells, 47.4% was bound to plasma proteins and 26.2% was present in the plasma water; its plasma protein binding amounted to 64.3%. Etomidate was bound at or in the blood cells, whereas R 28 141 was not.

Distribution, metabolism and excretion of etomidate, a short-acting hypnotic drug, in the rat. Comparative study of (R)-(+)-(--)-Etomidate.

Tritium-labelled (R)-(+) and (S)-(--)-etomidate was injected intravenously in male Wistar rats at four dose levels. Initial plasma clearance was high and the largest part of etomidate was rapidly distributed over those tissues, that had entered in equilibrium with plasma, such as brain, erythrocytes, heart, spleen, lung, kidney, muscle and intestines. Only in subcutaneous fat, testicles and stomach peak levels appeared after 28 minutes. The levels of etomidate, observed in all these tissues varied proportionally with the dose. Although the contents in brain of thw two isomers were comparable, only (R)-(+)-etomidate possesses hypnotic activity. The concentration in brain of (R)-(+)-etomidate, producing hypnotic activity in rats, was 1.50 +/- 0.35 mug/g tissues. Peak levels in liver appeared shortly after administration. Capacity-limited ester hydrolysis in the liver was the main metabolic pathway, yielding a single amphoteric metabolite. The rate of metabolization of (R)-(+)-etomidate was higher than that of the (S)-(--)-isomer. Excretion of the metabolite was mainly with the urine.