Isolation and structural characterization of the photolysis products of etoricoxib.

Etoricoxib is a potent and novel selective inhibitor of cyclooxygenase-2 (COX-2) which has been developed for the treatment of osteoarthritis, rheumatoid arthritis and several other inflammatory conditions. To support clinical pharmacokinetics studies, a method for the determination of etoricoxib in human plasma was developed. During the development of the method it was found that highly fluorescent products were formed when etoricoxib was exposed to UV light (254 nm). The formation of highly fluorescent products was the basis for the development of a highly sensitive HPLC/fluorescent assay for the indirect determination of etoricoxib in human plasma; the limit of quantification (LOQ) was 1 ng/mL. To unequivocally determine the chemical structures of the photolysis products of etoricoxib, a series of studies was conducted. When etoricoxib was irradiated online in a photochemical reactor, three products were detected in an HPLC-UV system. These products were characterized by HPLC-UV-fluorescence and HPLC-MS/MS. Possible structures of these products were proposed based on these data. The major photolysis products of etoricoxib were further isolated and their structures were elucidated using NMR and HPLC-NMR. The results of these experiments indicate that etoricoxib undergoes a photocyclization reaction when irradiated with UV light (254 nm), leading to the formation of two major isomeric photocyclization products.

Determination of efavirenz, a selective non-nucleoside reverse transcriptase inhibitor, in human plasma using HPLC with post-column photochemical derivatization and fluorescence detection.

Methods for the quantitative determination of efavirenz in human plasma and the qualitative assessment of the stereochemical integrity of efavirenz in post-dose human plasma samples are described. After the addition of an internal standard, plasma samples were extracted with hexane-methylene chloride (65/35, v/v%). The extracts were evaporated to dryness and reconstituted in mobile phase. Upon exposure to UV light, the analyte was found to form fluorescent products; the major fluorescent product was isolated and identified as a substituted quinoline. Thus, the plasma extracts were analyzed via HPLC with post-column photochemical derivatization and fluorescence detection. Reverse phase chromatography was used for the quantitative assay, whereas chromatography with a column containing a chiral stationary phase (dinitrobenzoyl leucine) was used for the stereochemical assessment. The quantitative assay has been validated in the concentration range of 50-1000 ng/ml using 0.5 ml samples. Analyte recovery was better than 89% at all points on the standard curve. Intra-day precision was better than 5% C.V., while accuracy was between 95 and 104% of nominal over the range of the assay. The selective detection method reduces the likelihood of interference by co-administered medications or endogenous species. The stereochemical configuration of efavirenz was confirmed to remain intact in post-dose human plasma samples. The quantitative method has been successfully utilized to support a study in which a possible drug interaction between co-administered HIV protease inhibitors and efavirenz was evaluated.

Improved procedure for the the determination of rofecoxib in human plasma involving 96-well solid-phase extraction and fluorescence detection.

An improved assay for the determination of rofecoxib in human plasma samples is described. The analyte and an internal standard were extracted from the plasma matrix using solid-phase extraction in the 96-well format with an Empore C8-SD extraction plate. The analytes are chromatographed on a Waters Symmetry C18 analytical column (3.5 microm, 50x4.6 mm) with a mobile phase consisting of acetonitrile-water (35:65, v/v). Analyte detection was via fluorescence following post-column photochemical derivatization. Eight point calibration curves over the concentration range of 0.5-80 ng/ml yielded a linear response when a 1/y weighted linear regression model was employed. Based on the replicate analyses (n=5) of spiked standards, the within-day assay precision was better than 8% RSD at all points on the calibration curve, within-day accuracy was within 6% of nominal at all standard concentrations. The between-run precision and accuracy of the assay, as calculated from the results of the analysis of quality control samples, was better than 7% RSD and within 5% of nominal. Assay throughput was improved by a factor of three as compared to previously described methods. The method was partially automated using a combination of a Packard Multi-Probe liquid handling system and a TomTec Quadra 96 workstation.

Dose proportionality of oral etoricoxib, a highly selective cyclooxygenase-2 inhibitor, in healthy volunteers.

To assess dose proportionality of etoricoxib across the anticipated clinical dose range, a single panel of 12 healthy subjects was administered single oral doses of etoricoxib of 5, 10, 20, 40, and 120 mg in an open, two-part, five-period crossover study. Plasma samples were collected aftereach dose and analyzed for etoricoxib concentrations. The pharmacokinetics of etoricoxib appear to be linear over the entire dose range examined, from 5 to 120 mg. Etoricoxib was found to be well tolerated across the 5 to 120 mg dose range.

High-throughput, semi-automated determination of a cyclooxygenase II inhibitor in human plasma and urine using solid-phase extraction in the 96-well format and high-performance liquid chromatography with post-column photochemical derivatization-fluorescence detection.

Compound I, 5-chloro-3-(4-methanesulfonylphenyl)-6'-methyl-[2,3']bipyridinyl, has been found to be a specific inhibitor of the enzyme cyclooxygenase II (COX II). The anti-inflammatory properties of this compound are currently being investigated. HPLC assays for the determination of this analyte in human plasma and human urine have been developed. Isolation of I and the internal standard (II) was achieved by solid-phase extraction (SPE) in the 96-well format. A C8 SPE plate was used for the extraction of the drug from human plasma (recovery >90%) while a mixed-mode (C8/Cation) SPE plate was used to isolate the analytes from human urine (recovery approximately 71%). The analyte and internal standard were chromatographed on a Keystone Scientific Prism-RP guard column (20 x 4.6 mm) connected to a Prism-RP analytical column (150 x 4.6 mm), using a mobile phase consisting of 45% acetonitrile in 10 mM acetate buffer (pH = 4); the analytes eluted at retention times of 5.2 and 6.9 min for I and II, respectively. Compounds I and II were found to form highly fluorescent products after exposure to UV light (254 nm). Thus, the analytes were detected by fluorescence (lambda(ex) = 260 nm, lambda(em) =375 nm) following post-column photochemical derivatization. Eight point calibration curves over the concentration range of 5-500 ng/ml for human plasma and human urine yielded a linear response (R2>0.99) when a 1/y weighted linear regression model was employed. Based on the replicate analyses (n = 5) of spiked standards, the within-day precision for both assays was better than 7% C.V. at all points on the calibration curve; within-day accuracy was within 5% of nominal at all standard concentrations. The between-run precision and accuracy of the assays, as calculated from the results of the analysis of quality control samples, was better than 8% C.V. and within 8% of nominal. I was found to be stable in human plasma and urine for at least 8 and 2 months, respectively. In addition, the human plasma assay was semi-automated in order to improve sample throughput by utilizing a Packard liquid handling system and a Tom-Tec Quadra 96 SPE system. The precision and accuracy of the semi-automated procedure were comparable to the manual procedure. Over 5000 clinical samples have been analyzed successfully using these methods.