Development and validation of a method for quantitative determination of valsartan in human plasma by liquid chromatography-tandem mass spectrometry.

A sensitive liquid chromatography-tandem mass spectrometry (LC-MS/MS) method for the determination of valsartan in human plasma was developed and validated. A 0.5 ml aliquot was extracted using solid-phase extraction in an Empore high performance extraction disk plate, universal resin 96-well format. The estimated calibration range of the method was 2-2000 ng/ml. The method was fully validated with intra-day mean accuracy and precision of 94.8-107% and 2.19-5.40% and inter-day mean accuracy and precision of 93.5-105% and 1.87-5.67%, respectively. No significant loss of valsartan in processed samples was confirmed in processed samples for up to 24 h at 10 degrees C. Sample dilution up to 50-fold with blank human plasma provided acceptable analyses. No interference peaks or matrix effects were observed. No effect of QC sample location results was observed in a 96-well plate. This LC-MS/MS technique was found to improve quantitative determination of valsartan allowing its pharmacokinetic evaluation with clinically relevant doses.

Population pharmacodynamic analysis of octreotide in acromegalic patients.

INTRODUCTION: Octreotide is an octapeptide analog of somatostatin used to normalize growth hormone levels in acromegaly. This article presents a population analysis of the relationship between octreotide and growth hormone concentrations in 94 patients with acromegaly, including 10 patients responding incompletely to subcutaneous treatment (poor responders). METHODS: Growth hormone and octreotide concentrations were recorded hourly over 12-hour time periods during long-term subcutaneous treatment. Twelve-hour profiles were also collected on different days up to 2 months after intramuscular injection of the long-acting formulation. We modeled the inhibition of growth hormone secretion by octreotide with a direct maximum inhibition model. A joint analysis of both formulations was performed with NONMEM (GloboMax, LLC, Hanover, Md). During model building, we examined the relationships between parameters and demographic covariates or formulations with the use of likelihood ratio tests. RESULTS: The baseline growth hormone level was higher in poor responders and was best described by a bimodal distribution. The maximum inhibition was common to both formulations and had a mean of 90%, with low interindividual variability. Sensitivity to octreotide (50% inhibitory concentration) was found to be slightly lower on average with intramuscular administration than with subcutaneous administration. CONCLUSION: Given adequate doses of octreotide, in 72% of 94 patients, growth hormone would decrease to levels below 2.5 ng. mL(-1), considered to be a desirable target concentration in acromegaly. This study provides a way to identify poor responders during subcutaneous treatment, allowing an early clinical decision to be made to switch nonresponders to alternative therapies.

Physiologically based pharmacokinetic (PBPK) modeling of everolimus (RAD001) in rats involving non-linear tissue uptake.

Everolimus is a novel macrolide immunosuppressant developed for the prophylaxis of allogeneic renal or cardiac transplant rejection. Treatments with immunosuppressants are often associated with organ toxicity that is linked to high organ exposure. Therefore, gaining insight into the pharmacokinetics of everolimus in various organs is highly desirable especially those organs of therapeutic interest or those that pose safety concerns. The aim of this work was to characterize the disposition kinetics of everolimus in rats by physiologically based pharmacokinetic (PBPK) modeling. Blood and tissue samples were collected from male Wistar rats over 24 hr following intravenous (iv) bolus and iv infusion of 1 mg/kg and 10 mg/kg/2 hr of everolimus. Further blood samples were collected between 1 and 170 hr from a third group of rats, which received iv infusion of 1 mg/kg/2 hr of everolimus. Drug concentrations in blood and tissues were determined by a liquid chromatography reverse dilution method. Distribution of everolimus between blood fractions was determined in vitro at 37 degrees C. The results of the study demonstrated that everolimus exhibited moderate non-linear binding to red blood cells. Also, the tissue-to-blood concentration ratio decreased in all tissues as blood concentration increased. A PBPK model involving non-linear tissue binding was able to successfully describe the observed data in blood and all the organs investigated. The highest binding potential was observed in thymus, lungs, and spleen with the greatest tissue affinity observed in thymus, skin, and muscle as compared to other tissues. Everolimus exhibited a high clearance rate that was limited to the hepatic blood flow (47.2 ml/min/kg). The PBPK model was also able to predict the venous blood concentration reasonably well following oral administration. The oral bioavailability value, as estimated with the PBPK, was 12% and was similar to the value obtained by non-compartmental analysis. In conclusion, A PBPK model has been developed that successfully predicts the time course of everolimus in blood and a variety of organs. This model takes into account the non- linear binding of everolimus to red blood cells and tissues. This model may be used to predict everolimus concentration-time course in organs from other species including humans.