Dissociation and electrooxidation of primaquine diphosphate as an approach to the study of anti-chagas prodrugs mechanism of action

Synthesis, Biological Activity and In Silico Pharmacokinetic Prediction of a New 2-Thioxo-Imidazoldidin-4-One of Primaquine

The discovery of novel antiparasitic drugs for neglected tropical diseases (NTDs) constitutes a global urgency and requires a range of innovative strategies to ensure a sustainable pipeline of lead compounds. Thus far, primaquine (PQ) is the only transmission-blocking antimalarial that is clinically available, displaying marked activity against gametocytes of all causative species of human malaria (Plasmodium spp.). Chagas disease, caused by Trypanosoma cruzi, is another PQ-sensitive illness besides malaria. One of the major drawbacks of PQ is its metabolism into carboxyprimaquine (CPQ), which is less active than the parent drug. In this study, we developed different synthetic pathways to confer N-protection to PQ through introduction of thioxo-imidazolidin-4-one. The introduction of this group prevents the formation of CPQ, counteracting one major drawback of the parent drug. After that, we evaluated the potential biological activity of the novel 2-thioxo-imidazolidin-4-one derivative of PQ, which showed relevant in vitro activity against Trypanosoma cruzi (IC₅₀ 1.4 μM) compared to PQ (IC₅₀ 1.7 μM) and the reference drug benznidazole (IC₅₀ 1.6 μM). Noting its acceptable pharmacokinetic profile, this PQ conjugate may be a potential scaffold for novel drug exploration against Chagas disease.

Receptor-mediated hepatocyte-targeted delivery of primaquine phosphate nanocarboplex using a carbohydrate ligand

Primaquine phosphate is a drug of choice for the treatment of malarial relapse. However, poor drug concentration in the hepatocytes and dose-related toxicity pose severe limitations. We report a nanocarboplex of primaquine phosphate by a simple in situ process using dextran sulphate as a carbohydrate polymer and pullulan as an asialoglycoprotein receptor ligand. Our aim was to preferentially enhance accumulation of the nanocarboplex in the hepatocytes. The in situ pullulan-anchored primaquine nanocarboplex was prepared by simple addition of a solution of dextran sulphate and pullulan with stabilizer to a measured quantity of primaquine phosphate in a vial, followed by shaking to obtain the primaquine phosphate nanocarboplex ready for injection. The nanocarboplex was characterized and evaluated in vivo for pharmacokinetics and biodistribution in the rat model. Specific uptake by hepatocytes in the liver was also quantified. Increase in t ½ with significant uptake in the RES organ was observed. More importantly, anchoring pullulan favored high liver uptake and preferential accumulation in the hepatocytes with a hepatocytes/nonparenchymal cells ratio of 75:25. The in situ primaquine phosphate nanocarboplex anchored with pullulan provides both a significant technological advantage and the desired targeting to the hepatocytes.

Electrochemical biosensors in pharmaceutical analysis

Given the increasing demand for practical and low-cost analytical techniques, biosensors have attracted attention for use in the quality analysis of drugs, medicines, and other analytes of interest in the pharmaceutical area. Biosensors allow quantification not only of the active component in pharmaceutical formulations, but also the analysis of degradation products and metabolites in biological fluids. Thus, this article presents a brief review of biosensor use in pharmaceutical analysis, focusing on enzymatic electrochemical sensors.

Analysis of albendazole metabolites by electrospray LC-MS/MS as a probe to elucidate electro-oxidation mechanism of albendazole

The electrochemical oxidation of albendazole was accomplished by controlled potential electrolysis technique. The oxidation was carried out in different pH solutions and yields the same products obtained by in vivo and in vitro metabolism, i.e. albendazole sulfoxide and albendazole sulfone. The identification of albendazole oxidation products was carried out by LC-MS/MS.