J. Godbillon

High-performance liquid chromatography of the aromatase inhibitor, letrozole, and its metabolite in biological fluids with automated liquid-solid extraction and fluorescence detection

An analytical method for the determination of letrozole (CGS 20,267) in plasma and of letrozole and its metabolite, CGP 44,645, in urine is described. Automated liquid-solid extraction of compounds from plasma and urine was performed on disposable 100-mg C8 columns using the ASPEC system. The separation was achieved on an ODS Hypersil C18 column using acetonitrile-phosphate buffer, pH 7, as the mobile phase at a flow-rate of 1.5 ml/min. A fluorescence detector was used for the quantitation. The excitation and emission wavelengths were 230 and 295 nm, respectively. The limits of quantitation (LOQ) of letrozole in plasma and in urine were 1.40 nmol/l (0.4 ng/ml) and 2.80 nmol/l, respectively. The respective mean recoveries and coefficient of variation (C.V.) were 96.5% (9.8%) in plasma and 104% (7.7%) in urine. The LOQ of CGP 44645 in urine was 8.54 nmol/l (2 ng/ml). The mean recovery was 108% (6.3%). The compounds were well separated from co-extracted endogenous components and no interferences were observed at the retention times of compounds. The sensitivity of this method for letrozole in plasma should be sufficient for kinetic studies in humans with single doses of 0.5 mg and possibly less.

The effect of age on the pharmacokinetics of valsartan

Twelve young (mean age 23 years, range 18–28) and 12 elderly (mean age 76 years, range 65–89) volunteers were given a single oral dose of 80 mg valsartan after an overnight fast. Each group consisted of six male and six female subjects. Mean systemic exposure to valsartan was higher in the elderly when compared with the young (AUC(0–24 h), 52% increase and AUC(0–∞), 70% increase). Variability, as shown by the coefficient of variation (CV), was larger for the elderly subjects and ANOVA of the log transformed AUC showed a significant difference between the two groups. This difference was largely brought about by five elderly subjects (one male, four females), whose AUC was about 2‐fold higher than the rest of the group. For the remaining elderly subjects, plasma valsartan AUC was similar to that observed for the young volunteers. This higher systemic exposure in five of the elderly subjects is not thought to be of clinical relevance when data from the patient population are considered. Other covariates—such as body weight, comedication, creatinine clearance, valsartan kinetics (absorption rate, distribution, and elimination)—did not explain the higher AUC in this subset of the elderly group. Data from the present study were compared with population kinetic data obtained from larger clinical trials including hypertensive patients in all age groups. Using this population approach, there was no difference in the pharmacokinetics of valsartan between male and female patients. Also, a relationship between plasma clearance of valsartan and age was established. The median age of patients in the hypertensive pool was 55 years. For an average 70‐year‐old patient, plasma clearance of valsartan is predicted to fall by 22% compared with an average 55‐year‐old. For the population, this difference is not sufficient to warrant initial dose adjustment based on age per se. The covariate age, does not completely explain the variability in the pharmacokinetics of valsartan within the general population. The treatment was well tolerated.

Automated microanalysis of oxcarbazepine and its monohydroxy and transdiol metabolites in plasma by liquid chromatography

An automated high-performance liquid chromatographic method for the simultaneous determination of oxcarbazepine and its monohydroxy and transdiol metabolites in plasma is described. 5,6-Dihydro-11-oxo-11H-dibenz[b,e]azepine-5-carboxamide was used as internal standard. Liquid-solid extraction from plasma (100 microliters) on 50 mg Bond-Elut C18 cartridges was automatically performed by the Automatic Sample Preparation with Extraction Columns (ASPEC) system. A reversed-phase column (ODS Hypersil, 3 microns particle size, 4 cm x 4.6 mm I.D.) was used with acetonitrile-methanol-0.01 M potassium dihydrogenphosphate as mobile phase. The eluted compounds were detected at 210 nm. The limit of quantitation was 0.2 mumol/l for oxcarbazepine and 0.1 mumol/l for its metabolites. No interference with concomitantly administered anti-epileptic drugs such as phenobarbital, phenytoin, valproic acid or carbamazepine, was found.

Determination of artemether and its metabolite, dihydroartemisinin, in plasma by high-performance liquid chromatography and electrochemical detection in the reductive mode

An analytical method for the determination of artemether (A) and its metabolite dihydroartemisinin (DHA) in human plasma has been developed and validated. The method is based on high-performance liquid chromatography (HPLC) and electrochemical detection in the reductive mode. A, DHA and artemisinin, the internal standard (I.S.), were extracted from plasma (1 ml) with 1-chlorobutane-isooctane (55:45, v/v). The solvent was transferred, evaporated to dryness under nitrogen and the residue dissolved in 600 microliters of water-ethyl alcohol (50:50, v/v). Chromatography was performed on a Nova-Pak CN, 4 microns analytical column (150 mm x 3.9 mm I.D.) at 35 degrees C. The mobile phase consisted of pH 5 acetate-acetonitrile (85:15, v/v) at a flow-rate of 1 ml/min. The analytes were detected by electrochemical detection in the reductive mode at a potential of -1.0 V. Intra-day accuracy and precision were assessed from the relative recoveries (found concentration in % of the nominal value) of spiked samples analysed on the same day (concentration range 10.9 to 202 ng/ml of A and 11.2 to 206 ng/ml of DHA in plasma). The mean recoveries over the entire concentration range were from 96 to 100% for A with C.V. from 6 to 13%, from 92% to 100% for DHA (alpha-tautomer) with C.V. from 4 to 16%. For A, the mean recovery was 96% at the limit of quantitation (LOQ) of 10.9 ng/ml with a C.V. of 13%. For DHA, the mean recovery was 100% at the LOQ of 11.2 ng/ml with a C.V. of 16%.

The influence of food on the disposition of the antiepileptic rufinamide in healthy volunteers

The effect of food on the pharmacokinetics of the antiepileptic rufinamide was investigated in healthy volunteers. Twelve subjects were treated with single per‐oral doses of 600 mg of rufinamide after overnight fasting or a fat and protein rich breakfast. Mean (±S.D.) areas under the plasma concentration–time curves (AUCs) of the unchanged compound were 57.2 (16) μg mL−1 h when given to the fasted volunteers and 81.7 (22.2) μg mL−1 h (p = 0.0001) when given after the breakfast. The average AUC was increased by 44% when rufinamide was given with food and the maximum concentration (Cmax) by about 100%. The time at which Cmax was reached (tmax) was shorter (8 h in fasted conditions and 6 h in fed after breakfast); the terminal half‐life was not influenced by concomitant intake of food.

Automated and sensitive method for the determination of formoterol in human plasma by high-performance liquid chromatography and electrochemical detection

An automated high-performance liquid chromatography (HPLC) method for the determination of formoterol in human plasma with improved sensitivity has been developed and validated. Formoterol and CGP 47086, the internal standard, were extracted from plasma (1 ml) using a cation-exchange solid-phase extraction (SPE) cartridge. The compounds were eluted with pH 6 buffer solution-methanol (70:30, v/v) and the eluate was further diluted with water. An aliquot of the extract solution was injected and analyzed by HPLC. The extraction, dilution, injection and chromatographic analysis were combined and automated using the automate (ASPEC) system. The chromatographic separations were achieved on a 5 microm, Hypersil ODS analytical column (200 mm x 3 mm I.D.), using (pH 6 phosphate buffer, 0.035 M + 20 mg/l EDTA)-MeOH-CH3CN (70:25:5, v/v/v) as the mobile phase at a flow-rate of 0.4 ml/min. The analytes were detected with electrochemical detection at an operating potential of +0.63 V. Intra-day accuracy and precision were assessed from the relative recoveries of calibration/quality control plasma samples in the concentration range of 7.14 to 238 pmol/l of formoterol base. The accuracy over the entire concentration range varied from 81 to 105%, and the precision (C.V.) ranged from 3 to 14%. Inter-day accuracy and precision were assessed in the concentration range of 11.9 to 238 pmol/l of formoterol base in plasma. The accuracy over the entire concentration range varied from 98 to 109%, and precision ranged from 8 to 19%. At the limit of quantitation (LOQ) of 11.9 pmol/l for inter-day measurements, the recovery value was 109% and C.V. was 19%. As shown from intra-day accuracy and precision results, favorable conditions (a newly used column, a newly washed detector cell and moderate residual cell current level) allowed us to reach a LOQ of 7.14 pmol/l of formoterol base (3 pg/ml of formoterol fumarate dihydrate). Improvement of the limit of detection by a factor of about 10 was reached as compared to the previously described methods. The method has been applied for quantifying formoterol in plasma after 120 microg drug inhalation to volunteers. Formoterol was still measurable at 24 h post-dosing in most subjects and a slow elimination of formoterol from plasma beyond 6-8 h after inhalation was demonstrated for the first time thanks to the sensitivity of the method.

Simultaneous determination of imipramine and its metabolite desipramine in human plasma by capillary gas chromatography with mass-selective detection

An analytical method for the simultaneous determination of imipramine (IMI) and its N-desmethyl metabolite, desipramine (DIMI) in human plasma by capillary gas chromatography-mass selective detection (GC-MS), with D4-imipramine (D4-IMI) and D4-desipramine (D4-DIMI) as internal standards, was developed and validated. After addition of the internal standards, the compounds were extracted from plasma at basic pH into n-heptane-isoamyl alcohol (99:1, v/v), back-extracted into acidic aqueous solution and re-extracted at basic pH into toluene. Desipramine and D4-desipramine were converted into their pentafluoropropionyl derivatives. The compounds were determined by gas chromatography using a mass selective detector at m/z 234 for IMI, m/z 238 for D4-IMI, m/z 412 for DIMI and m/z 416 for D4-DIMI. The method was applied to clinical samples.

Determination of diclofenac in plasma and urine by capillary gas chromatography—mass spectrometry with possible simultaneous determination of deuterium-labelled diclofenac

A specific and sensitive method for the determination of diclofenac at concentrations down to ca. 1 ng/ml, the limit of detection being 100 pg/ml, in human plasma and urine by gas chromatography-mass spectrometry with 2H4-labelled diclofenac as internal standard is described. The method is also suitable for the simultaneous assay of these two compounds when both are present in samples of human plasma or urine. In this case, 5-chlorodiclofenac is used as internal standard. After toluene extraction from plasma or without extraction for urine, the method involves the formation of a dimethylindolinone derivative by extractive alkylation. The technique was applied to determine low plasma concentrations and urinary excretion of labelled and unlabelled diclofenac after percutaneous applications of Voltaren Emulgel to humans applied simultaneously under occlusive dressing as deuterated diclofenac sodium, and without occlusive dressing as unlabelled diclofenac sodium.

Determination of metoprolol and its α-hydroxylated metabolite in human plasma by high-performance liquid chromatography

A high-performance liquid chromatographic method has been developed for the simultaneous determination of metoprolol and its alpha-hydroxylated metabolite in plasma, Metoprolol, alpha-hydroxymetoprolol and alprenolol (internal standard) are extracted from plasma at alkaline pH with diethyl ether-dichloromethane (4:1, v/v) and back-extracted with 0.01 N sulfuric acid. A 100-microliter volume of the acidic extract is injected into the chromatographic system. The compounds are eluted in about 12 min with acetonitrile-acetate buffer (75:25, v/v) on a LiChrosorb RP-8 (5 micron) column. The quantitative determinations are made fluorometrically. Concentrations down to 35 nmol/1 (10 ng/ml) of metoprolol base and 30 nmol/1 (8 ng/ml) of alpha-hydroxymetoprolol base in plasma can be determined with good precision and accuracy.

Automated analysis of a novel anti-epileptic compound, CGP 33 101, and its metabolite, CGP 47 292, in body fluids by high-performance liquid chromatography and liquid-solid extraction

Automated procedures for the determination of CGP 33,101 in plasma and the simultaneous determination of CGP 33,101 and its carboxylic acid metabolite, CGP 47,292, in urine are described. Plasma was diluted with water and urine with a pH 2 buffer prior to extraction. The compounds were automatically extracted on reversed-phase extraction columns and injected onto an HPLC system by the automatic sample preparation with extraction columns (ASPEC) automate. A Superlosil LC-18 (5 microns) column was used for chromatography. The mobile phase was a mixture of an aqueous solution of potassium dihydrogen phosphate, acetonitrile and methanol for the assay in plasma, and of an aqueous solution of tetrabutylammonium hydrogen sulfate, tripotassium phosphate and phosphoric acid and of acetonitrile for the assay in urine. The compounds were detected at 230 nm. The limit of quantitation was 0.11 mumol/l (25 ng/ml) for the assay of CGP 33,101 in plasma, 11 mumol/l (2.5 micrograms/ml) for its assay in urine and 21 mumol/l (5 micrograms/ml) for the assay of CGP 47,292 in urine.