The application of fully automated on-line solid phase extraction in bioanalysis.

This paper describes the application of fully automated on-line solid phase extraction to the bioanalysis of three example compounds using the Symbiosis platform. The on-line assay performance is compared to off-line methodologies for the same compounds. The three example compounds possess a variety of physicochemical properties and different extraction modes were applied in off-line methods. These methods were developed through optimisation of solid phase or liquid-liquid extraction and chromatographic separation conditions for each of the analytes. Both on-line and off-line methods were evaluated for linearity, carryover, imprecision and inaccuracy. Experiments were also performed investigating modification of ionisation and selectivity against different batches of plasma. On-line and off-line methods were found to be comparable in performance. In conclusion, on-line methodology has distinct advantages for the analysis of large numbers of samples with a marked reduction in manual operation.

Determination of a potent urokinase-type plasminogen activator, UK-356,202, in plasma at pg/mL levels using column-switching HPLC and fluorescence detection.

A rapid, sensitive and selective method using column-switching HPLC with fluorescence detection has been developed for the determination of UK-356,202, a potent urokinase-type plasminogen activator, in human plasma. A structural isomer of UK-356,202 is used as an internal standard. The lower limit of quantification is 20 pg/mL and the method is linear over a 100-fold concentration range. UK-356,202 is extracted from plasma simply through the removal of proteins by precipitation with acetonitrile. The HPLC system comprises three columns and the cycle time is 9.5 min per sample. The eluate from the extraction column is heart-cut onto a trace enrichment cartridge which is then back-flushed onto a narrow-bore Supelco ABZ+ Plus analytical column. The method has been used to analyze many thousands of samples from clinical and toxicological studies support. Its ruggedness is demonstrated by the use of a single extraction column for the analysis of over 1200 clinical samples.

Assessment of the absorption, metabolism and absolute bioavailability of maraviroc in healthy male subjects.

AIMS: Two studies were conducted to: (i) quantify the amount of drug-related radioactivity in blood, plasma, urine and faeces following a (14)C-labelled dose of maraviroc; and (ii) investigate the pharmacokinetics, safety and tolerability of intravenous (i.v.) maraviroc and determine the absolute bioavailability of oral maraviroc. Metabolite profiling was also conducted. Data from both of these studies were used to construct a mass-balance model for maraviroc. METHODS: Study 1 was an open-label study in three healthy male subjects. All subjects received a single 300-mg oral solution dose of (14)C-labelled maraviroc. Study 2 included two cohorts of subjects. Cohort 1 involved a double-blind (third party open), four-way crossover study where eight subjects received escalating i.v. doses of maraviroc (3, 10 and 30 mg) with placebo insertion. Cohort 2 involved an open, two-way crossover study where 12 subjects received 30 mg maraviroc by i.v. infusion and 100 mg maraviroc orally in random order. In study 1, blood samples and all urine and faeces were collected up to at least 120 h postdose. In study 2, blood samples were taken at intervals up to 48 h postdose. Urine was also collected up to 24 h postdose in cohort 1 only. RESULTS: After oral administration in study 1, maraviroc was rapidly absorbed with a plasma T(max) reached by 2 h postdose for all three subjects. The maximum concentrations of radioactivity also occurred within 2 h for all subjects. There was a higher amount of radioactivity in plasma than in blood (blood/plasma ratio approximately 0.6 for AUC(t) and C(max)). Unchanged maraviroc was the major circulating component in plasma, accounting for approximately 42% of the circulating radioactivity. Following a 300-mg (14)C-labelled maraviroc dose, means of 76.4% and 19.6% of radioactivity were recovered in the faeces and urine, respectively. The mean total recovery of dosed radioactivity was 96%, with the majority of radioactivity being recovered within 96 h postdose. Profiling of the urine and faeces showed similar and extensive metabolism in all subjects. Unchanged maraviroc was the major excreted component (33%). The major metabolic pathways were determined and involved oxidation and N-dealkylation. Intravenous doses of maraviroc (3-30 mg) were well tolerated in study 2, and drug exposure was approximately proportional to dose within the studied range. Approximately 23% of total clearance (44 l h(-1)) was accounted for by renal clearance (10.2 l h(-1)). Mean volume of distribution at steady state was 194 l. Absolute bioavailability of a 100-mg oral tablet dose, by comparison with a 30-mg i.v. dose, was calculated to be 23.1%. CONCLUSIONS: Maraviroc is rapidly absorbed and extensively metabolized, although unchanged maraviroc is the major circulating component in plasma and is the major excreted component after oral dosing. The pharmacokinetics of maraviroc after i.v. administration is approximately proportional over the dose range studied. Renal clearance contributes 23% of total clearance. The absolute bioavailability of 100 mg oral maraviroc is 23%.

The use of 96-well Scintiplates to facilitate definitive metabolism studies for drug candidates.

Semi-quantitative analysis of the drug-related components in biological samples collected during definitive metabolism studies using radiolabelled drug candidates is commonly achieved by HPLC profiling, using either on-line radiochemical detection or off-line liquid scintillation counting (LSC) following collection of the HPLC eluent into vials. However, although the use of LSC with vials has high sensitivity, the approach is time-consuming, laborious and destructive, whilst on-line detection methods are inappropriate for samples with low-levels of radioactivity (commonly the case with plasma samples). The use of 96-well microtitre plates (Scintiplates) for fraction collection during HPLC profiling provides a sensitive, effective and efficient alternative method for the semi-quantitative analysis of radiolabelled components in biological samples. Furthermore, the approach is non-destructive, such that subsequent identification of the isolated components can be achieved. Although the Scintiplate methodology is not appropriate for the analysis of excreta samples, where quenching of the radiochemical signal by endogenous components was observed, the approach was demonstrated to be valid for the relative quantification of [14C]-labelled material in plasma samples for all species investigated. In addition, good sensitivity was observed, with a counting efficiency of 79% for [14C], such that a drug-related component accounting for 10-15 dpm is quantifiable. The utility of the methodology for profiling circulating metabolites was demonstrated by the analysis of a rat plasma sample following oral administration of [14C]-UK-349,862. The Scintiplate approach and subsequent mass spectrometric analysis resulted in the relative quantitation and specific characterisation of circulating metabolites accounting for 93% of the total plasma radioactivity.

Comparative human pharmacokinetics and metabolism of single-dose oral and intravenous sildenafil.

AIMS: To characterize the absorption, metabolism and excretion of an oral and intravenous (IV) dose of radiolabelled [14C]-sildenafil citrate in healthy male subjects. Specific objectives were to measure the cumulative amount of drug-related radiolabelled material excreted in the urine and faeces to characterize urinary and faecal radioactivity as unchanged sildenafil or its metabolites, and to quantify blood and plasma total radioactivity and unchanged drug concentrations. METHODS: Six healthy male subjects between the ages of 45 and 58 years were enrolled in an open-label, parallel-group study; three subjects received the oral dose and three received the IV dose. Oral drug was administered as a single dose of 50-mg [14C]-sildenafil, and IV drug was administered as a single dose of 25-mg [14C]-sildenafil infused over 25 min. Each dosage form contained 50 microCi of radioactivity. For radioactivity assays, whole blood, plasma, urine and faeces samples were taken predose and at specified intervals up to 5 days postdose. Plasma samples were assayed for sildenafil and the metabolites UK-103,320 and UK-150,564. Metabolite profiling was also performed in plasma, faeces and urine. RESULTS: Absorption of sildenafil after oral administration was rapid and approximately 92% whilst the absolute bioavailability was limited to 38%, due to first-pass metabolism. Mean AUCt values showed that sildenafil accounted for about 60% of the total circulating radioactivity in the plasma after IV administration and for 32% after oral administration. Concentrations of radioactivity in whole blood were lower than in plasma, indicating limited penetration of sildenafil into blood cells. No unchanged sildenafil was detected in either urine or faeces, demonstrating that metabolism was the major mechanism of drug clearance. The principal routes of metabolism were N-demethylation, oxidation and aliphatic dehydroxylation. Sildenafil was well tolerated, with treatment-related adverse events reported by three subjects. Two of these were mild, and there was one case of moderate leg pain. CONCLUSIONS: The pharmacokinetics of radiolabelled [14C]-sildenafil were consistent with rapid absorption, first-pass metabolism and primarily faecal elimination of N-demethylated metabolites.