Development of an LC-MS method to quantify coproporphyrin I and III as endogenous biomarkers for drug transporter-mediated drug-drug interactions.

Coproporphyrins are proposed as endogenous biomarkers of hepatic Organic Anion Transporting Polypeptide (OATP)1B functional activity. In this study, a new sample extraction method based on a mixed-mode anion exchange sorbent (SPE clean-up using Oasis 30mg Max 96 well plates) was developed for absolute quantification of coproporphyrin I and III (CP-I and CP-III) in human plasma. Chromatographic separation was performed with an Ace Excel 2 C18 PFP, 3µm, 2.1×150mm, maintained at 60°C. A 10mM ammonium formate containing 0.1% HCOOH and acetonitrile (100%) was used as mobile phase A and B, respectively. Mass transition, m/z 655.3→596.3 was selected to monitor CP-I and CP-III, while m/z 659.3→600.3 transition was used for the stable isotope labelled internal standard. Optimization of the liquid chromatography tandem mass spectrometry method ensured a lower limit of quantification (LLOQ) of 20pg/mL. Both CP-I and CP-III had extraction recoveries of 70%. The calibration range was 0.02-100ng/mL for both CP-I and CP-III, yielding calibration curves with correlation coefficients greater than 0.988. Inter day precision (CV<9%) and accuracy (84.3-103.9%) complied with the recommendation of the European Bioanalytical Forum. The optimized method was used to analyse plasma samples originating from three independent clinical studies. Obtained CP-I and CP-III plasma baseline levels in healthy volunteers were in good agreement with previously published data. Moreover, CP-I and CP-III plasma levels in human subjects dosed with a clinically confirmed OATP inhibitor were significantly increased compared to their baseline levels. These data demonstrate the potential of CP-I and CP-III as endogenous biomarkers to predict the drug-drug interaction (DDI) related to hepatic OATP1B inhibition. Stability of CP-I and CP-III in plasma and solvents under different processing and storage conditions was also evaluated.

The application of capillary microsampling in GLP toxicology studies.

AIM: Capillary microsampling (CMS) to collect microplasma volumes is gradually replacing traditional, larger volume sampling from rats in GLP toxicology studies. METHODOLOGY: About 32 µl of blood is collected with a capillary, processed to plasma and stored in a 10- or 4-µl capillary which is washed out further downstream in the laboratory. CMS has been standardized with respect to materials, assay validation experiments and application for sample analysis. CONCLUSION: The implementation of CMS has resulted in blood volume reductions in the rat from 300 to 32 µl per time point and the elimination of toxicokinetic satellite groups in the majority of the rat GLP toxicology studies. The technique has been successfully applied in 26 GLP studies for 12 different projects thus far.

Assessment of light stability of drugs in blood and plasma.

AIM: A procedure was developed for the assessment of photochemical stability of drugs in blood and plasma under standardized conditions. The procedure avoids a variable outcome of photochemical stability experiments and tests relevant worst case conditions so that unnecessary light protection is avoided. Results/methodology: Blood and plasma were spiked with a mixture of drugs and incubated in a Suntest CPS(+), in the laboratory on the bench and near the window on a sunny summer day. The results were compared. DISCUSSION/CONCLUSION: No protection from light, limited protection from light and full protection from light are advised for drugs that are stable in plasma in the Suntest CPS(+) at 250 W/m(2) for at least 30 min, for 5-30 min and for <5 min, respectively.

Evaluation of the diagnostic potential of urinary N-Acetyltyramine-O,ß-glucuronide (NATOG) as diagnostic biomarker for Onchocerca volvulus infection.

BACKGROUND: Onchocerciasis, also known as river blindness is one of the neglected tropical diseases affecting millions of people, mainly in sub-Saharan Africa and is caused by the filarial nematode Onchocerca volvulus. Efforts to eliminate this disease are ongoing and are based on mass drug administration programs with the microfilaricide ivermectin. In order to monitor the efficacy of these programs, there is an unmet need for diagnostic tools capable of identifying infected patients. We have investigated the diagnostic potential of urinary N-acetyltyramine-O,ß-glucuronide (NATOG), which is a promising O. volvulus specific biomarker previously identified by urine metabolome analysis. METHODS: A liquid chromatography tandem mass spectrometry (LC-MS/MS) method was used to assess the stability characteristics of NATOG and to evaluate the levels of NATOG in study samples. An LC-fluorescence method was also developed. RESULTS: Stability characteristics of NATOG were investigated and shown to be ideally suited for use in tropical settings. Also, an easy and more accessible method based on liquid chromatography coupled to fluorescence detection was developed and shown to have the necessary sensitivity (limit of quantification 1 µM). Furthermore, we have evaluated the levels of NATOG in a population of 98 nodule-positive individuals from Ghana with no or low levels of microfilaria in the skin and compared them with the levels observed in different control groups (endemic controls (n = 50), non-endemic controls (n = 18) and lymphatic filariasis (n = 51). Only a few (5 %) of nodule-positive individuals showed an increased level (> 10 µM) of NATOG and there was no statistical difference between the nodule-positive individuals and the control groups (P > 0.05). CONCLUSIONS: Results of the present study indicate the limited potential of NATOG as a diagnostic biomarker for O. volvulus infection in amicrofilaridermic individuals.

Tissue distribution and depletion kinetics of bortezomib and bortezomib-related radioactivity in male rats after single and repeated intravenous injection of 14 C-bortezomib.

PURPOSE: The body distribution of total radioactivity (TR) and bortezomib was investigated in male Sprague-Dawley rats after single and repeated i.v. (bolus) administration with (14)C-labelled bortezomib (VELCADE) (0.2 mg/kg; 0.28 MBq./kg). METHODS: Bortezomib was dosed on days 1, 4, 8, and 11 (i.e. a clinical dosing cycle) and the animals were sacrificed at selected time points following single and repeated dose administration for the quantification of TR in blood, plasma, and various tissues by liquid scintillation counting following organ dissection or by quantitative whole body autoradiography. In selected tissues, bortezomib levels were determined by LC-MS/MS. RESULTS: In general, plasma TR levels were less than 10% of the corresponding blood concentrations. TR was rapidly and widely distributed to the tissues with only limited penetration into the central nervous system (CNS). In the tissues, highest levels of TR were measured in bortezomib-eliminating organs (liver and kidney), lymphoid tissues, and regions of rapidly dividing cells (e.g. the bone marrow, intestinal mucosa). Low TR concentrations were found in the CNS (tissue-to-blood ratio of approximately 0.05 after repeated dosing). With the exception of the liver, TR consisted almost exclusively of the parent drug. Tissue concentrations of TR and bortezomib increased up to about threefold from the first to the third dose administration, after which they remained constant. CONCLUSION: No undue tissue accumulation of TR and of bortezomib was observed in rats following a full clinical dosing cycle of bortezomib.