Novel micro-extraction by packed sorbent procedure for the liquid chromatographic analysis of antiepileptic drugs in human plasma and urine.

A method for the simultaneous determination of the antiepileptic drugs, phenobarbital (PHB), phenytoin (PTN), carbamazepine (CBZ), primidone (PRM) and oxcarbazepine (OXC) in human plasma and urine samples by using micro-extraction in a packed syringe as the sample preparation method connected with LC/UV (MEPS/LC/UV) is described. Micro-extraction in a packed syringe (MEPS) is a new miniaturized, solid-phase extraction technique that can be connected online to gas or liquid chromatography without any modifications. In MEPS approximately 1 mg of the solid packing material is inserted into a syringe (100-250 µL) as a plug. Sample preparation takes place on the packed bed. The bed can be coated to provide selective and suitable sampling conditions. The new method is very promising, easy to use, fully automated, inexpensive and quick. The standard curves were obtained within the concentration range 1-500 ng/mL in both plasma and urine samples. The results showed high correlation coefficients (R(2) >0.988) for all of the analytes within the calibration range. The extraction recovery was found to be between 88.56 and 99.38%. The limit of quantification was found to be between 0.132 and 1.956 ng/mL. The precision (RSD) values of quality control samples (QC) had a maximum deviation of 4.9%. A comparison of the detection limits with similar methods indicates high sensitivity of the present method. The method is applied for the analysis of these drugs in real urine and plasma samples of epileptic patients.

Simultaneous determination of phenytoin and dextromethorphan in urine by solid-phase extraction and HPLC-DAD.

A rapid and simple high-performance liquid chromatographic method with photodiode array detection was developed for the separation and the simultaneous determination of phenytoin and dextromethorphan in human urine. Analysis was performed in less than 4.5 min in isocratic mode on a reversed-phase C18 column (5 microm; 150 x 4.6 mm) using a mobile phase composed of acetonitrile-buffer phosphate 0.01 M (60:40, v/v) adjusted to pH 6.0, at 1 mL/min flow rate and UV absorbance at 210 nm. The elution order of analytes was dextromethorphan (DXM), Internal Standard (IS), and phenytoin (PHT). Calibration curves were linear in the 7.5-25 microg/mL range for PHT and in the 10-30 microg/mL range for DXM. Spike recoveries for urine samples prepared at three spiking levels ranged from 97.8 to 102.3% for PHT and from 94.8 to 100.4% for DXM. The detection limit (LOD) values ranged from 0.08 microg/mL for PHT to 0.5 microg/mL for DXM. The quantitation limit (LOQ) values ranged from 0.3 microg/mL for PHT to 1.6 microg/mL for DXM. The sample preparation method involves a rapid and simple procedure based on solid-phase extraction using a C18 reversed-phase column. Validation of the optimised method was carried out according to the ICH guidelines. The method developed in this study allows the reliable simultaneous analysis of PHT and DXM, drugs that were never quantified together in previously reported analytical methods. The described method has the advantage of being rapid and easy and it could be applied in therapeutic monitoring of these drugs in human urine of epileptic patients.

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.

Simultaneous determination of primidone and its three major metabolites in rat urine by high-performance liquid chromatography using solid-phase extraction.

A new high-performance liquid chromatographic method for simultaneous determination of primidone (PRM) and of its three major metabolites, phenobarbital (PB), p-hydroxyphenobarbital (p-HO-PB) and phenylethylmalonamide (PEMA), in rat urine, was developed. After acid hydrolysis, these compounds were extracted from urine by means of a Bond Elut Certify LRC column with good clean-up. The extracts were chromatographed on a C18 reversed-phase column using isocratic elution at 40 degrees C, with UV detection at 227 nm. The limit of detection was 0.5 mg/ml for the four compounds. Good linearity (r2>0.99) was observed within the calibration ranges studied: 37.4-299.3 microg/ml for PRM, 26.4-211.2 microg/ml for PB, 12.5-100.2 microg/ml for p-HO-PB and 12.1-97.0 microg/ml for PEMA. Repeatability was in the range 3.1-6.8%. This method constitutes a useful tool for studies on the influence of various parameters on primidone metabolism.

Simultaneous determination of carbamazepine, phenytoin, phenobarbital, primidone and their principal metabolites by high-performance liquid chromatography with photodiode-array detection.

We have established a precise and accurate high-performance liquid chromatographic method for the simultaneous assay of carbamazepine, phenytoin, phenobarbital, primidone and their principal metabolites. This method has been used for the analysis of these drugs and the metabolites in serum, saliva and urine samples. Acetonitrile is used for the deproteinization of serum and saliva samples while solid-phase extraction is utilized for urine sample pretreatment. Samples of 2 microliters are injected onto a 3-microns ODS-Hypersil column (250 mm x 2 mm I.D.) with a column temperature of 40 degrees C. The drugs and metabolites are eluted with a mobile phase containing potassium phosphate buffer-acetonitrile-methanol (110:50:30, v/v/v) at a flow-rate of 0.2 ml/min. Signals are monitored by a photodiode-array detector at a sample wavelength of 200 nm with a bandwidth of 10 nm. These four commonly used antiepileptic drugs and their six metabolites are well separated from one another within 15 min. Within-day coefficients of variation (C.V.) are within 5% in most cases and between-day C.V. are from 2.32 to 4.75%. The recovery rates range from 95.12 to 104.42%. This method has the necessary sensitivity and linearity for routine therapeutic monitoring of both total and free drug levels and may be employed for pharmacokinetics studies of drug interactions and metabolism as well.

Urinary metabolites of phenobarbitone, primidone, and their N-methyl and N-ethyl derivatives in humans.

1. Phenobarbitone (1) and three of its N-alkyl derivatives, and primidone (10) and four of its N-alkyl derivatives, were orally administered separately to two human volunteers. Total urine was collected for approximately 2 weeks following each dose, and the drugs and their metabolites were assayed by g.l.c.-mass spectrometry. 2. Recoveries in the phenobarbitone series increased from approximately 40% to approximately 50% as alkylation of (1) increased. There was a linear relationship between the extent of p-hydroxylation and the lipophilicity (log P) of the substrates. The increased total recovery was largely attributable to increased p-hydroxylation. 3. Urinary recoveries in the primidone series decreased from approximately 80% for (10) to approximately 30% for its diakyl derivatives, despite a slight increase in p-hydroxylation with increasing alkylation (and increasing lipophilicity). The decreased recovery was mainly the result of decreased urinary excretion of the drug.

Metabolic studies with phenobarbitone, primidone and their N-alkyl derivatives: quantification of substrates and metabolites using chemical ionization gas chromatography-mass spectrometry.

Metabolic studies with phenobarbitone, primidone and some of their N-alkyl derivatives required the concurrent assay of any mixture of these substrates (twelve compounds) and their major metabolites (an additional twenty-two compounds) in urine. The method described in the present report met this requirement by incorporating two complementary derivatization techniques into a gas chromatographic-mass spectrometric (GC-MS) assay procedure. Following hydrolysis of conjugates with beta-glucuronidase, urine samples were extracted with ethyl acetate (3 X 5 ml). The combined extracts were dried over sodium sulphate, divided into two equal portions, and the solvent was removed. One residue was derivatized by propylation using 1-iodopropane with base catalysis. The other residue was silylated using methyl-N-(tert.-butyldimethylsilyl)trifluoroacetamide. The derivatives in each case were analysed by GC-MS, using temperature-programmed packed-column GC and chemical ionization MS. Mass spectra were acquired over an appropriate mass range, and peak areas for the compounds of interest were determined from specific mass chromatograms. Satisfactory precision, accuracy, specificity and sensitivity were obtained for all analytes. All compounds produced satisfactory derivatives by at least one procedure; twelve compounds could be analysed by both techniques. The method illustrates the utility of chemical ionization GC-MS for the simultaneous quantitative analysis of multiple related analytes in complex biological samples.

Primidone crystalluria following overdose. A report of a case and an analysis of the literature.

Seven cases of crystalluria following primidone overdose have been reported since the 1950s. An eighth case of primidone crystalluria following overdose is presented. Because of low aqueous solubility (600 mg/L at 37 degrees C) which is directly proportional to temperature, any factor increasing renal excretion of unchanged primidone predisposes to crystal formation. Renal clearance is dependent on dosage because of negligible protein binding, zero-order conversion to phenobarbitone (phenobarbital) and first-order conversion to phenylethylmalonamide. Therapy with other anticonvulsants known to induce the metabolism to phenobarbitone does not appear to be protective against crystalluria in overdose situations. The critical serum primidone concentration for crystalluria presence seems to be 80 mg/L. There is evidence for nephrotoxicity of the crystals themselves if formed in vivo (actual crystal presence during voiding). The chemical phenomenon of supersaturation of a solution is protective against in vivo crystal formation with subsequent nephrotoxicity. Vigorous hydration to augment elimination and to lessen the propensity for renal toxicity is recommended.

Kinetics of primidone metabolism and excretion in children.

The metabolism and excretion of orally administered primidone was studied in 12 children, aged 7 to 14 yr during long-term dosing. Plasma concentrations of primidone (Pr) peaked at 4 to 6 hr and declined exponentially from 6 to 24 hr, with half-life (t1/2) values ranging from 4.5 to 11 hr. A mean of 92% (72% to 123%) of the administered dose was recovered within 24 hr from the urine as Pr and its metabolites. Of the total Pr daily dose, 42.3% (15.2% to 65.9%) was recovered as unchanged drug, 45.2% (16.3% to 65.3%) as phenylethylmalonamide (PEMA), and 4.9% (1.1% to 8.0%) as phenobarbital (Pb). The mean rate constant for conversion of Pr to PEMA (K1) was 0.0424 hr-1, for conversion of Pr to Pb (K2) was 0.0045 hr-1, and for excretion of unchanged Pr (K3) was 0.0389 hr-1. Of Pb excreted, 43% (13% to 100%) was unchanged, 15% (0% to 27%) was unconjugated p-OH Pb, 20% (0% to 44%) was conjugated p-OH Pb, and 22% (0% to 33%) was conjugated 3,4-OH Pb. KE appears to be important determinant of the steady-state plasma concentration of Pb, but interindividual differences in K2 have little influence on the overall rate constant for elimination of Pr.

Acetazolamide-induced interference with primidone absorption. Case reports and metabolic studies.

Effects of acetazolamide on primidone plasma levels were studied in three patients. Apparent interaction occurred in two patients. Primidone was not detected in the plasma when given orally with acetazolamide in one patient. In another, peak serum concentration was delayed, with corresponding delays in urinary excretion of primidone and metabolites. Plasma and urine concentrations of the two metabolites, phenylethylmalonamide and phenobarbital, were also studied.

Acute primidone overdosage with massive crystalluria.

A patient admitted to the hospital in coma was found to have massive primidone crystalluria. Gas chromatographic analysis of blood and urine for primidone and phenobarbital showed high urine primidone levels and high blood phenobarbital levels. The primidone levels suggest that primidone is rapidly cleared into urine. The high blood phenobarbital levels within 12 hr of overdosage with a history of diphenylhydantoin therapy and without phenobarbital therapy or overdosage suggests that diphenylhydantoin may influence the metabolic conversion of primidone to phenobarbital. The relationship of clinical symptomatology to high levels of primidone and phenobarbital is unclear. Analysis of blood and urine for primidone and phenobarbital and urine for crystals is of value in establishing diagnosis and prognosis in cases of suspected primidone overdosage.