Daniela Gonçales Rando

Prodrugs for the Treatment of Neglected Diseases

Recently, World Health Organization (WHO) and Medicins San Frontieres (MSF) proposed a classification of diseases as global, neglected and extremely neglected. Global diseases, such as cancer, cardiovascular and mental (CNS) diseases represent the targets of the majority of the R&D efforts of pharmaceutical companies. Neglected diseases affect millions of people in the world yet existing drug therapy is limited and often inappropriate. Furthermore, extremely neglected diseases affect people living under miserable conditions who barely have access to the bare necessities for survival. Most of these diseases are excluded from the goals of the R&D programs in the pharmaceutical industry and therefore fall outside the pharmaceutical market. About 14 million people, mainly in developing countries, die each year from infectious diseases. From 1975 to 1999, 1393 new drugs were approved yet only 1% were for the treatment of neglected diseases [3]. These numbers have not changed until now, so in those countries there is an urgent need for the design and synthesis of new drugs and in this area the prodrug approach is a very interesting field. It provides, among other effects, activity improvements and toxicity decreases for current and new drugs, improving market availability. It is worth noting that it is essential in drug design to save time and money, and prodrug approaches can be considered of high interest in this respect. The present review covers 20 years of research on the design of prodrugs for the treatment of neglected and extremely neglected diseases such as Chagas’ disease (American trypanosomiasis), sleeping sickness (African trypanosomiasis), malaria, sickle cell disease, tuberculosis, leishmaniasis and schistosomiasis.

Antileishmanial activity screening of 5-nitro-2-heterocyclic benzylidene hydrazides

A series of 53 nitro derivatives rationally designed were obtained by parallel synthesis and screened against Leishmania donovani. Six compounds exhibited IC(50) values lower than standard drugs. Brief SAR analysis revealed that substitution is important to the activity. Nitrothiophene analogues were more potent than the nitrofuran ones. This was attributed to the ability of sulfur atoms in accommodating electrons from nitro group, which facilitate its reduction and therefore the formation of free radicals lethal to parasites.

New antitumoral agents I: In vitro anticancer activity and in vivo acute toxicity of synthetic 1,5-bis(4-hydroxy-3-methoxyphenyl)-1,4-pentadien-3-one and derivatives

This paper describes a new method for the preparation of 1,5-bis(4-hydroxy-3-methoxyphenyl)-1,4-pentadien-3-one 1 and its derivatives 2-5. This set of synthetic compounds exhibited high antitumoral activities regarding in vitro screening against several human tumor cell lines as lung carcinoma NCI-460, melanoma UACC-62, breast MCF-7, colon HT-29, renal 786-O, ovarian OVCAR-03 and ovarian expressing the resistance phenotype for adriamycin NCI-ADR/RES, prostate PC-3, and leukemia K-562. Compounds were also tested against murine tumor cell line B16F10 melanoma and lymphocytic leukemia L1210 as well as to their effect toward normal macrophages. Specific activity against colon cancer cells HT-29 was observed for all tested compounds and suggests further studies with models of colon cancer. Compounds 1, 2, and 4 showed significant cytotoxic activity with IC(50) values 2.3 microM for all human cancer cell lines. Intraperitoneal acute administration of compound 1 and 2 showed very low toxicity rate.

Use of N-methylene phosphonic chitosan to obtain an isoniazid prodrug

Tuberculosis(TB) is one of the most neglected health problems and has been out of control in many areas of the world. Since new antituberculous alternatives, including controlled classical drug delivery systems, are urgently needed to face this serious situation, the purpose of the present work was the synthesis and characterization of a prolonged action prodrug of isoniazid. The N-methylene phosphonic chitosan (NMPC), a hydrosoluble derivative of chitosan was used as drug carrier. This analog, as well as its precursor, exhibits stimulatory activity on macrophages, host cells of Mycobacterium tuberculosis. Due to its hydrosolubility, it can be easily handled and intravenously administrated. The NMPC can be obtained by reaction of chitosan with phosphorous acid in presence of formaldehyde. Once synthesized, the coupling with isoniazid was carried out after two steps: functionalization of the drug with a succinic spacer group and activation of the succinyl isoniazid through the cyclic analog 1-(pyridine-4-carbonyl)-tetrahydro-pirydazin-3,6-dione.

4‐(2‐Isonicotinoyl­hydrazino)‐4‐oxobutanoic acid

The title compound, C10H11N3O4, was synthesized by reacting isoniazid with succinic anhydride. The structure reveals an infinite two-dimensional network in the (011) plane, stabilized by intermolecular hydrogen bonds. Three of these hydrogen bonds are symmetrically independent.

Seleno and Telluro Cyclofunctionalization of α,γ-Diallyl-β-ketoesters: Polysubstituted Furan Derivatives

Abstract Seleno- and telurocyclofunctionalized furan derivatives were prepared by reaction of phenylselenenyl bromide and p-methoxyphenyl tellurium trichloride with α,γ-diallyl-β-ketoesters in good yield.

Molecular modeling approach to predict a binding mode for the complex methotrexate-carboxypeptidase G2.

Carboxypeptidase G2 (CPG2) is a zinc-metalloenzyme employed in a range of cancer chemotherapy strategies by activating selectively nontoxic prodrugs into cytotoxic drugs in tumor as well as in the treatment of intoxication caused by high-doses of the anticancer drug methotrexate (MTX). CPG2 catalyzes the hydrolytic cleavage of C-terminal of glutamate moiety from folic acid and analogues. Regardless of its extensive application, its mechanism of catalysis has not yet been determined and, so far, no co-crystallized complex has been published. So, in this study, molecular docking and a short molecular dynamics (MD) simulation sampling scheme, as a function of temperature, were performed to investigate a possible binding mode for MTX, a recognized substrate of CPG2. The findings suggested that MTX interacts possibly in quite specific points of the CPG2 active site, which are probably responsible for the molecular recognition and cleavage procedures. The MTX substrate fits well in the catalytic site by accommodating the pteridine moiety in an adjacent pocket to the active site whereas a glutamate moiety is pointed toward the protein surface. Additionally, a glutamate residue can interact with a crystallization water molecule in the active site, supporting its activation as a nucleophilic group.