Effects of encapsulation of primidone on its oxidative metabolism in rats.

The aim of this study was to evaluate the influence of primidone (PRM) nanoencapsulation on its metabolism. Suspensions of PRM powder and PRM-loaded poly-epsilon-caprolactone nanocapsules were administered orally in the same way to rats. Primidone-loaded poly-epsilon-caprolactone nanocapsules were prepared according to the interfacial deposition technique. Free PRM suspensions were obtained by addition of PRM powder to a suspension of 0.212% carboxymethylcellulose CMC 12H in water. The dose was 20 mg/kg, n = 6, for each experiment. Urinary and faecal levels of PRM and of its three major metabolites, phenylethylmalonamide (PEMA), phenobarbital (PB), and p-hydroxyphenobarbital (p-HO-PB), were determined. Concentrations were evaluated by high-performance liquid chromatography (HPLC) according to a validated analytical method. After PRM nanocapsule administration, non-metabolised PRM urinary levels were increased compared to those observed after administration of a suspension of primidone powder (43.7+/-8.8% after PRM-loaded nanocapsule and 37.7+/-8.1% after free PRM administration). For phenylethylmalonamide, no difference was observed in urinary excretion in the two cases. For two of the oxidised metabolites, PB and p-HO-PB, excretion was delayed and shortened. The amount of these oxidised metabolites was lowered from 0.95% after free PRM administration to 0.25% after PRM-loaded nanocapsule administration. No difference was noted in non-metabolised primidone excretion in faeces. These results suggest that primidone-loaded nanocapsules could be used as a vehicle for oral primidone administration in order to minimise the phenobarbital metabolic pathway.

Studies on the intracerebral metabolism of anticonvulsant drugs--I. Perfusion of primidone through the isolated brain of the rat.

Primidone and phenobarbital (each 85 nmoles/ml were separately perfused through the isolated brain of the rat. After 5 min of perfusion similar amounts of primidone and phenobarbital were taken up into the brain; for both drugs the concentration ratio between brain and perfusion medium was about 0.2. However, after 2 hr of perfusion the mean concentration ratio for primidone was about 0.55; for phenobarbital it was about 0.9 thus indicating a better uptake of phenobarbital. In two regions (hypophysis, mesencephalon) the concentration of phenobarbital was significantly higher than in perfusion medium. During 2 hr of perfusion of primidone, substantial quantities of phenobarbital and PEMA were formed amounting to 1400 pmoles for each metabolite. The highest concentration of the metabolites was found in septum, hypothalamus, hypophysis and mesencephalon. The in situ metabolism of primidone in the intact brain was demonstrated for the first time.

Anticonvulsant effect of primidone in the gerbil. Time course and significance of the active metabolites.

The anticonvulsant effect of primidone was determined in gerbils, in which seizures were elicited by a blast of compressed air, over the time range of 30 min to 18 h after oral administration. ED50s remained fairly constant from 1 to 12 h after administration: 46-73 mumol/kg with the minimal value at 6 h. Of the metabolites, phenobarbital was maximally effective at 2 h after administration (ED50 35 mumol/kg), whereas phenylethylmalondiamide (PEMA) only had a weak anticonvulsant effect (ED50 1.55 mmol/kg at 2 h). By determination of primidone and its active metabolites in plasma and brain at 1, 4 and 12 h after administration of the respective ED50s, it could be shown that unchanged primidone is mostly responsible for the anticonvulsant effect of the first hours, but, at 12 h, only phenobarbital could be detected in both tissues. PEMA could not be detected in brain. From the effective brain concentrations at different times it could be calculated that primidone and phenobarbital have the same anticonvulsant potency on a molar base in the gerbil. The concentrations necessary to control seizures in this model were considerably lower than those needed to suppress convulsions in maximal seizure models in mice and rats.

Pharmacokinetics of phenylethylmalonamide (PEMA) after oral and intravenous administration.

The pharmacokinetics of phenylethylmalonamide (PEMA), one of the major metabolites of the antiepileptic drug primidone, have been studied in 6 healthy volunteers after administration of single 500mg intravenous and oral doses. Following intravenous administration, after a very short distributive phase (t1/2 = 0.23-0.53h), the decline of the log-PEMA concentration with respect to time appeared linear. The pharmacokinetic parameters, calculated according to a 1-compartment open model, showed the following values (mean +/- SD): terminal half-life, 15.7 +/- 3.4h; apparent volume of distribution, 0.69 +/- 0.10 L/kg; total serum clearance, 31.3 +/- 6.6 ml/h/kg. After oral administration, peak serum concentrations occurred at 0.5 to 4 hours and the oral bioavailability was 86.4 to 95.9%.

Interactions between primidone, carbamazepine, and nicotinamide.

The effect of nicotinamide on the conversion of primidone to phenobarbital was studied in mice and in three epileptic patients. In mice, 200 mg per kilogram of nicotinamide increased the half-life of primidone by 47.6%, and the conversion to phenobarbital and phenylethylmalonamide was decreased by 32.4% and 14.5%, respectively. Nicotinamide also decreased the conversion of primidone to phenobarbital in patients. The dose of nicotinamide correlated directly with the primidone-phenobarbital ratio (r = 0.861, p less than 0.01). Nicotinamide also increased carbamazepine levels in two patients treated with this drug. The data demonstrate that nicotinamide inhibits metabolism of primidone in mice and metabolism of primidone and carbamazepine in humans. This probably occurs by inhibition of cytochrome P-450 by nicotinamide.

Phenytoin: an inhibitor and inducer of primidone metabolism in an epileptic patient.

The interaction between primidone and phenytoin was studied in an epileptic patient treated with primidone only and primidone plus phenytoin for 3 months. Plasma and urine levels of drugs and metabolites were monitored daily by GC and GC-MS. The addition of phenytoin to the regimen increased steady-state plasma levels of phenobarbitone and phenylethylmalonamide (PEMA), metabolites of primidone, and decreased levels of primidone and unconjugated p-hydroxyphenobarbitone (p-OHPB), a metabolite of phenobarbitone. After withdrawal of phenytoin, plasma phenobarbitone and primidone levels slowly returned to previous steady-state levels, PEMA rapidly decreased to lower levels than before, and p-OHPB levels rose rapidly. Urinary excretion of primidone and its metabolites paralleled the changes in their plasma levels after the addition of phenytoin but the percentage of unconjugated p-OHPB in urine was unchanged during the course of the study. In conclusion phenytoin initially induces the conversion of primidone to PEMA and phenobarbitone, although each to a different extent, but it appears to inhibit the hydroxylation of phenobarbitone. Thus, two apparently contradictory phenomena seem to be involved in the primidone-phenytoin interaction. The net effect is an enhanced increase in plasma phenobarbitone levels.

Pharmacokinetics of phenylethylmalonamide (PEMA) in normal subjects and in patients treated with antiepileptic drugs.

The pharmacokinetics of phenylethylmalonamide (PEMA), a major metabolite of primidone, were investigated following administration of single oral doses (400 mg) to six normal subjects and six patients receiving chronic treatment with antiepileptic drugs. Peak serum PEMA levels were usually attained with 2-4 h after intake. The oral bioavailability estimated on the basis of the recovery of unchanged drug in the urine of normal subjects was at least 80%. Half-life values ranged from 17 to 25 h in normal subjects and from 10 to 23 h in the patients. No statistically significant difference in any of the calculated kinetic parameters could be found between the two groups. The data indicate that PEMA is readily absorbed from the gastrointestinal tract and that it is eliminated predominantly unchanged in the urine of man.