Study of the in vitro metabolic profile of a new α2-adrenergic agonist in rat and human liver microsomes by using liquid chromatography-multiple-stage mass spectrometry and nuclear magnetic resonance.

A potent synthetic α2-adrenergic agonist called PT-31, (3-(2-chloro-6-fluorobenzyl)-imidazolidine-2,4-dione), was recently detected as a potential drug to be used as an adjuvant drug to treat chronic pain. The excellent pharmacological property of PT-31 highlights the importance in elucidating its metabolism, which could provide valuable information about its metabolite profile for further pharmacokinetics studies and additionally to estimate the impact of its metabolites on the efficacy, safety and elimination of PT-31. In this work, the study of the in vitro metabolism of PT-31 was initially carried out by using a liquid chromatography coupled to ion trap multiple-stage mass spectrometer (LC-IT-MSn) and a hybrid triple quadrupole/linear ion trap mass spectrometer (LC-QTrap). The production of at least three unknown oxidative metabolites was observed. Structural identification of the unknown metabolites was carried out by combination of LC-MS experiments, including selected reaction monitoring (SRM) and multi-stage full scan experiments. Further analysis of 1H-NMR led to the structural confirmation of the major metabolite. The results indicated that PT-31 was metabolized by a hydroxylation reaction in the imidazolidine-2,4-dione ring in rat and human liver microsomes, producing the metabolite 3-(2-chloro-6-fluorobenzyl)-5-hydroxyimidazolidine-2,4-dione in rat liver microsomes. A carbon hydroxylation onto the benzyl ring, produced two other minor metabolites of the PT-31 in rat liver microsomes.

Development and validation of a UHPLC-MS/MS bioanalytical method to quantify in plasma the analgesic candidate PT-31 following a preliminary pharmacokinetic study in rats.

A selective and sensitive UHPLC-MS/MS bioanalytical method to determine PT-31, an analgesic drug candidate, in rat plasma was developed and validated. Analyses were performed using a UHPLC-MS/MS system equipped with an electrospray ionization interface operating in the positive ionization mode using a C18 reversed-phase column with a mobile phase of water:acetonitrile (68:31, v/v) containing 0.1% acetic acid eluting in a gradient mode with a flow rate of 0.3 mL/min. Plasma samples were deproteinized with cold acetonitrile containing 0.01% TFA (1:2, v/v) and 50 µL of the supernatant were injected into the system. PT-31 and phenytoin (internal standard) retention times were roughly 1.0 and 1.5 min, respectively. Linear standard curves were plotted for the 0.01-10 µg/mL concentration range, with a coefficient of determination > 0.99. The method's precision was over 88%. Maximum intra- and inter-day relative standard deviations were 14.6% and 11.6%, respectively. Interfering substances were not detected in the chromatogram, indicating that the method was specific. PT-31 stability was assessed under different temperature and storage settings. The method was used to characterize PT-31 plasma pharmacokinetics following administration of 5 mg/kg i.v. to Wistar rats. Therefore, the method described is sensitive, linear, precise and specific enough to determine PT-31 in preclinical pharmacokinetic investigations. Copyright © 2015 John Wiley & Sons, Ltd.

Compostos coordenados híbridos de platina no tratamento do câncer / Platinum hybrid coordinated compounds in cancertreatment

O câncer, ou neoplasia, é uma doença caracterizada pela propagação descontrolada de formas anormais das próprias células corporais e corresponde à segunda doença que mais causa mortes no mundo. A história da platina no tratamento do câncer teve início com a descoberta da sua atividade, em 1965, com a aprovação para uso clínico acontecendo apenas após 10 anos. Atualmente, os fármacos com platina estão entre os mais bem sucedidos agentes anticancerígenos, onde se destacam cisplatina (1), carboplatina (2) e oxaliplatina (3). Seus mecanismos de ação são similares: estes fármacos formam adutos com o DNA, impedindo a sua síntese e reparo, levando à morte celular. Contudo, os efeitos adversos desencadeados pelo tratamento e o desenvolvimento de resistência ao medicamento têm limitado suas aplicações. Uma das principais estratégias para a diminuição de tais efeitos consiste em alterar a estrutura destas moléculas, levando à formação de compostos híbridos, que se caracterizam pela presença de pelo menos dois fragmentos funcionais distintos em uma mesma molécula e podem apresentar maior espectro de atividade antitumoral. Dentre as alterações mais comuns encontram-se a modificação da solubilidade, através da inserção de grupos abandonadores mais ou menos hidrofóbicos e a introdução de ligantes com atividade biológica própria. Dessa forma, esta revisão visa verificar os avanços mais recentes na síntese de compostos híbridos de platina, bem como as melhorias na atividade anticâncer dos novos compostos platinados...

Cancer, or neoplasm, is a disease characterized by the uncontrolled propagation of abnormal cells of the body and is the second leading death-causing disease. The history of platinum in cancer treatment goes back to the discovery of its activity in 1965 and its approval for clinical use just 10 years later. Some of the most successful anticancer agents are Pt-based chemotherapeutics, among which cisplatin (1), carboplatin (2), and oxaliplatin (3) stand out. They have similar mechanisms of action: they form adducts with DNA, preventing its synthesis and repair and leading to cell death. However, adverse effects triggered by treatment and the development of resistance to these drugs have limited their application. One of the most important strategies to reduce such effects is to carry out structural modifications of these molecules, leading to hybrid compounds that are characterized by the presence of at least two distinct functional fragments on the same molecule and can exhibit a broader antitumor activity spectrum. Among the most typical modifications are changes to the solubility pattern, created by the insertion of leaving groups with high or low hydrophobicity, and the introduction of biologically active ligands as non-leaving groups. The purpose of these strategies is to obtain compounds capable of reducing systemic toxicity and/or overcoming acquired resistance factors to cisplatin. Therefore, the aim of this review is to discuss the most recent advances in the synthesis of hybrid platinum compounds, as well as improvements in the anticancer activity of Pt-compounds...