Therapeutic monitoring of anticonvulsant drugs: gas-chromatographic simultaneous determination of primidone, phenylethylmalonamide, carbamazepine, and diphenylhydantoin.
(1/9)
We describe a sensitive and precise gas-chromatographic method in which benzylmalonate methylester monoamide is used as the internal standard for the simultaneous determination of primidone, phenylethylmalonamide, carbamazepine, and diphenylhydantoin. The trimethylsilyl derivatives of the anticonvulsants are well separated from each other and from normal serum constituents. The lower limit of detection for each drug is 0.5 mg/liter when 1 ml of serum is analyzed. Within-run precision (CV), established by analysis of 10 replicates, was as follows: primidone (5.4 mg/liter), 2.6%; phenylethylmalonamide (5.5 mg/liter), diphenylhydantoin (6.6 mg/liter), 3.8%; and carbamazepine (10.4 mg/liter), 3.2%. Fifty specimens were analyzed for primidone and 35 for diphenylhydantoin by a standard gas-chromatographic method involving on-column methylation and by the procedure we have developed. The mean value observed for primidone with the on-column alkylation procedure was 9.3 mg/liter and with our procedure was 9.6 mg/liter. When values for our assay were regressed against values for the standard method, the slope of the least-squares line was 0.936, the intercept was 1.00 mg/liter, and r was 0.939. The mean values observed for diphenylhydantoin by on-column methylation and with our procedure were both 12.6 mg/liter. When values for our assay were regressed against the standard method, the slope of the least-squares line was 0.944, the intercept was 0.3 mg/liter, and r was 0.988. (+info)
Simultaneous plasma lamotrigine analysis with carbamazepine, carbamazepine 10,11 epoxide, primidone, phenytoin, phenobarbital, and PEMA by micellar electrokinetic capillary chromatography (MECC).
(2/9)
The determination of lamotrigine (LTG) simultaneously with carbamazepine (CBZ), carbamazepine 10,11 epoxide (CBZ-E), primidone (PRM), phenytoin (PHT), phenobarbital (PB), and 2-phenyl-2-ethyl-malonamide (PEMA) in human plasma was developed using micellar electrokinetic capillary chromatography (MECC) with a diode-array detector. The reproducibility of both separation and quantitation with MECC analysis were appropriate for the intra- and interassay coefficients. The evaluated drugs concentration intervals of LTG, 0.5-10.0 micro g/mL; CBZ, 1.0-16.0 micro g/mL; PEMA, 1.0-20.0 micro g/mL; PB, 1.0-60.0 micro g/mL; PRM, 1.0-20.0 micro g/mL; PHT, 0.7-40.0 micro g/mL; and CBZ-E, 1.0-14.0 micro g/mL were linear with correlation coefficients higher than 0.987 and coefficients of the variation of the points of the calibration curve lower than 10%. The limit of quantitation of the investigated drugs in plasma varied from 0.5 to 1.0 micro g/mL, depending upon the drug. The MECC technique was sensitive enough to work with microsamples into the subtherapeutic, therapeutic, and toxic concentrations, as well as showed to be simple and efficient when applied to monitoring therapeutic drugs in patients treated with a combination of lamotrigine and other antiepileptic drugs such as hepatic enzyme-inducing agents. (+info)
The disposition of primidone in elderly patients.
(3/9)
1. The pharmacokinetics and metabolism of primidone at steady-state were studied in 10 elderly patients aged 70-81 years and eight control subjects aged 18-26 years. 2. Primidone half-lives and clearance values (mean +/- s.d.) were similar in the elderly and in the young (12.1 +/- 4.6 vs 14.7 +/- 3.5 h and 34.8 +/- 9.0 vs 33.2 +/- 7.2 ml h-1 kg-1 respectively. 3. The serum concentrations of the metabolites phenylethylmalonamide (PEMA) and phenobarbitone relative to those of parent drug were higher in the elderly than in the young, the difference being significant (P less than 0.01) in the case of PEMA. 4. The renal clearances of primidone, phenobarbitone and PEMA were moderately decreased in the elderly but this reduction was statistically significant only for PEMA. Elderly patients excreted a reduced proportion of unchanged primidone and an increased proportion of PEMA in urine. 5. Ageing is associated with a greater accumulation of PEMA, which is unlikely to have a major clinical significance. (+info)
Benign familial tremor treated with primidone.
(4/9)
Primidone given to a patient for epilepsy produced an unexpected reduction in benign familial tremor. Over the next eight years the drug was therefore tried in a prospective study of 20 other patients with benign familial tremor alone. Of these, six could not tolerate the drug because of vertigo and nausea but 12 obtained a good response, which in some cases was dramatic. Investigations in two patients suggested that the effect was mediated predominantly by derived phenylethylmalonamide, though primidone had some effect, since tremor recurred slightly on withdrawing the drug despite a constant or rising blood phenylethylmalonamide concentration. Primidone is highly effective in benign familial tremor. More patients with the condition are intolerant of the drug than are usually found with epilepsy. (+info)
Phenylethylmalonamide in essential tremor. A double-blind controlled study.
(5/9)
A randomised double-blind placebo-controlled trial of phenylethylmalonamide, the major metabolite of primidone was performed in eight patients with essential tremor. Phenylethylmalonamide was given in a daily dose of 400 mg for one week and 800 mg for a second week. The compound had no statistically significant effect on the amplitude of tremor assessed by an accelerometric method, tests of performance, clinical evaluation and patient self assessment. No side effects occurred. Serum levels of phenylethylmalonamide on a daily dose of 400 mg were 11-27 micrograms/ml and on 800 mg daily were 16-48.5 micrograms/ml. (+info)
Phenytoin: an inhibitor and inducer of primidone metabolism in an epileptic patient.
(6/9)
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. (+info)
The effects of phenytoin on phenobarbitone and primidone metabolism.
(7/9)
Serum concentrations of primidone and its metabolites-phenobarbitone and phenylethylmalonamide-were measured in 40 epileptic patients receiving treatment with primidone alone or primidone plus phenytoin. Serum phenobarbitone concentrations were also measured in 100 patients receiving phenobarbitone, alone or with phenytoin showed raised serum phenobarbitone concentrations. Phenytoin also caused raised phenylethylmalonamide concentrations in patients on primidone. (+info)
Monitoring 2-ethyl-2-phenylmalonamide in serum by gas-liquid chromatography: application to retrospective study in epilepsy patients dosed with primidone.
(8/9)
We describe a procedure for determining 2-ethyl-2-phenylmalonamide (I) in serum of epilepsy patients dosed with primidone (II) for seizure control, by extracting the sample with chloroform under basic conditions, with use of an internal standard, 2-ethyl-2-(p-tolyl)malonamide, and without derivative formation. The sensitivity limit is 1.0 mg/L. Within-run CVs for 5, 10, and 30 mg/L concentrations were 3.5, 2.5, and 0.7%, respectively. For a 1.0 mg/kg body wt per day dose of II in patients co-medicated with phenytoin (Group A), the mean steady-state concentrations of I, II, and phenobarbital (III) were 0.72, 0.62, and 2.24 mg/L, respectively. For patients co-medicated with carbamazepine and phenytoin (Group B), I, II, and III concentrations were 0.68, 0.44, and 2.12 mg/L, respectively. Between these groups, only for II were the concentrations statistically different (t = 2.762; p < 0.01). For Group A no correlation was found between II and III. For Groups A and B, the coefficients of correlation between I and III were 0.626 and 0.826, respectively. (+info)