SB-83, a 2-Amino-thiophene derivative orally bioavailable candidate for the leishmaniasis treatment.

Leishmaniasis, affecting more than 12 million people worldwide has become a severe public-health problem. The therapeutic arsenal against leishmaniasis is mainly administered by parenteral route; it is toxic, expensive, and associated with recurrence risk. The need for further therapeutic compounds research is pressing. In previous studies, we demonstrated the antileishmanial activities of ten 2-amino-thiophene derivatives, which evidenced the action of a compound, called SB-83, having expressive antileishmania activity in an in vitro infection model. In the present work, we describe preclinical studies of the thiophenic derivative SB-83, such as acute toxicity, genotoxicity, in vivo oral efficacy in a murine model, and in vitro antileishmanial activity against an L. amazonensis SbIII-resistant strain. Determining acute preclinical toxicity, the LD50 of SB-83 was estimated at 2500 mg/kg orally, with few behavioral changes in Swiss mice. Further, treatment with 2000 mg/kg of SB-83 did not induce in vivo genotoxic activity in the peripheral blood micronucleus assay. In 7 weeks of oral treatment, SB-83 reduced paw lesion size in L. amazonensis infected mice by 52.47 ± 5.32%, and decreased the parasite load of the popliteal lymph node and spleen at the highest dose tested (200 mg/kg) respectively by 42.57 ± 3.14%, and 100%, without presenting weight change or other changes of clinical importance in the biochemical and hematological profiles. The treatment of promastigotes and intracellular amastigotes of SbIII sensitive and resistant strains with SB-83 did not produce differences in antileishmania activity, which suggests no cross-resistance. Thus, this work demonstrated that SB-83 has potential as a new active drug candidate even when orally administered, which may become a new therapeutic alternative for the treatment of leishmaniasis.

Drug discovery and computational strategies in the multitarget drugs era

The pharmaceutical industry is increasingly joining chemoinformatics in the search for the development of new drugs to be used in the treatment of diseases. These computational studies have the advantage of being less expensive and optimize the study time, and thus the interest in this area is increasing. Among the techniques used is the development of multitarget directed ligands (MTDLs), which has become an ascending technique, mainly due to the improvement in the quality of treatment involving several drugs. Multitarget therapy is more effective than traditional drug therapy that emphasizes maximum selectivity for a single target. In this review a multitarget drug survey was carried out as a promising strategy in several important diseases: neglected diseases, neurodegenerative diseases, AIDS, and cancer. In addition, we discuss Computer-Aided Drug Design (CADD) techniques as a tool in the projection of multitarget compounds against these diseases.

A new acridine derivative induces cell cycle arrest and antiangiogenic effect on Ehrlich ascites carcinoma model.

BACKGROUND: Acridine derivatives, including amsacrine, have antitumor activity. However, side effects, development of resistance and their low bioavailability, have limited their use. Herein, we described the synthesis, and evaluated the toxicity and antitumor activity of a new amsacrine analogous, the N'-(2-chloro-6-methoxy-acridin-9-yl)-2-cyano-3-(4-dimethylaminophenyl)-acrilohidrazida (ACS-AZ10). METHODS: The compound was obtained in a linear pathway where the ASC-Az intermediate was obtained by coupling of 6,9-dichloro-3-methoxy-acridine and 2-ciany-acethohidrazide followed by condensation with the corresponding aldehyde. The toxicity of ACS-AZ10 was evaluated in mice using acute toxicity and micronucleus assays. Ehrlich ascites carcinoma model was used to investigate the antitumor activity and toxicity of ACS-AZ10 (7.5, 15 or 30mg/kg, i.p.), after nine days of treatment. Cell cycle and angiogenesis were also evaluated. RESULTS: The ASC-AZ10 was obtained with satisfactory yields and its structure was confirmed by spectroscopic and spectrometric techniques. On acute toxicity study, ACS-AZ10 (2000mg/kg, i.p.) induced transient depressant effects on central nervous system. The LD50 was approximately 2500mg/kg. ACS-AZ10 (15 or 30mg/kg) displayed significant antitumor activity considering the tumor weight and volume, cell viability, and total Ehrlich cell count. ACS-AZ10 (7.5mg/kg) induced an increase in sub-G1 peak, suggesting apoptosis. At 15mg/kg ACS-AZ10 induced cell cycle arrest in G2/M phase and a reduction in the percentage of cells in G0/G1 and S phases, suggesting a pre-mitotic blockade. ACS-AZ10 reduced the microvessel density, indicating an antiangiogenic effect. Weak hematological, biochemical and histopathological toxicity were observed. The compound doesn't show genotoxicity in micronucleus assay. CONCLUSIONS: ACS-AZ10 has potent antitumor activity in vivo along with low toxicity.