Beatriz S. Parajón-Costa

Abstract: As a contribution to the development of novel vanadium complexes with pharmacologically interesting moieties, new dioxovanadium(V) semicarbazone complexes with the formula cis-VO(2)L, where L=5-bromosalicylaldehyde semicarbazone and 2-hydroxynaphtalen-1-carboxaldehyde semicarbazone have been synthesized and characterized by (1)H and (13)C NMR, Raman and FTIR spectroscopies. Results were compared with those previously reported for other three analogous complexes of this series. The five complexes were tested in three different human tumor cell lines for bioactivity as potential anti-tumor agents, showing selective cytotoxicity on TK-10 cell line. Results showed that structural modifications on the semicarbazone moiety could have a significant effect on the anti-tumor activity of the vanadium complexes. In addition, the electrochemical behavior of all the complexes was studied. No apparent correlation could be demonstrated between reduction potentials of the complexes and their anti-tumor activities. The molecular structure of the novel [V(V)O(2)(5-bromosalicylaldehyde semicarbazone)] complex was solved by X-ray diffraction methods. The vanadium atom shows a distorted square pyramidal coordination sphere. The (VO(2))(+) cation is coordinated to a nearly planar (L)(-) anion acting as a tridentate ligand through both oxygen and one nitrogen atoms.

Abstract: The reaction of [VO(dipic)(H2O)2] · H2O with creatinine in a H2O–CH3OH mixture yields yellow crystals of a bis(oxo-bridged) binuclear vanadium(V) compound of stoichiometry [CH3NHC(NH2)2]2[V2O4(dipic)2], (dipic2− = pyridine 2,6 dicarboxylate; CH 3 NHC ( NH 2 ) 2 + ) = methylguanidinum ) The molecular structure of the compound was determined by X-ray diffraction methods The binuclear complex crystallizes in the monoclinic space group P21/c with a = 9557(1), b = 12363(1), c = 10466(1) A, β = 10156 (2)° and Z = 2 It sits at a crystallographic inversion center with the pair of V(V) atoms in an edge-sharing distorted octahedral environment In the [VO2(dipic)]− halves of the dimer, the VO 2 + cation is coordinated to a dipicolinate group acting as a tridentate planar ligand through one oxygen of each carboxylic group and the hetereocyclic nitrogen atom The oxo ligand lying near the coordination plane bridges through a weak axial V–O bond to the other half of the dimer This gives rise to a V O2 bond length slightly longer than the other terminal V O1 bond The infrared and Raman spectra of the compound were recorded and discussed on the basis of its structural data and compared with those of the free acid The results are also compared with the corresponding results of related structures

Abstract: In the search for new metal-based drugs for the treatment of Chagas disease, the most widespread Latin American parasitic disease, novel complexes of the bioactive ligand risedronate (Ris, (1-hydroxy-1-phosphono-2-pyridin-3-yl-ethyl)phosphonate), [M(II)(Ris)(2)]·4H(2)O, where M═Cu, Co, Mn and Ni, and [Ni(II)(Ris)(2)(H(2)O)(2)]·H(2)O were synthesized and characterized by using analytical measurements, thermogravimetric analyses, cyclic voltammetry and infrared and Raman spectroscopies. Crystal structures of [Cu(II)(Ris)(2)]·4H(2)O and [Ni(II)(Ris)(2)(H(2)O)(2)]·H(2)O were solved by single crystal X-ray diffraction methods. The complexes, as well as the free ligand, were evaluated in vitro against epimastigotes and intracellular amastigotes of the parasite Trypanosoma cruzi, causative agent of Chagas disease. Results demonstrated that the coordination of risedronate to different metal ions improved the antiproliferative effect against T. cruzi, exhibiting growth inhibition values against the intracellular amastigotes ranging the low micromolar levels. In addition, this strong activity could be related to high inhibition of farnesyl diphosphate synthase enzyme. On the other hand, protein interaction studies showed that all the complexes strongly interact with albumin thus providing a suitable means of transporting them to tissues in vivo.

Abstract: In the search for new therapeutic tools against Chagas disease (American trypanosomiasis) palladium and platinum complexes of the bioactive ligand pyridine-2-thiol N-oxide were exhaustively characterized and evaluated in vitro. Both complexes showed high in vitro growth inhibition activity (IC(50) values in the nanomolar range) against Trypanosoma cruzi, the causative agent of the disease. They were 39-115 times more active than the antitrypanosomal drug Nifurtimox. The palladium complex showed an approximately threefold enhancement of the activity compared with the parent compound. In addition, owing to their low unspecific cytotoxicity on mammalian cells, the complexes showed a highly selective antiparasite activity. To get an insight into the mechanism of action of these compounds, DNA, redox metabolism (intraparasite free-radical production) and two parasite-specific enzymes absent in the host, namely, trypanothione reductase and NADH-fumarate reductase, were evaluated as potential parasite targets. Additionally, the effect of metal coordination on the free radical scavenger capacity previously reported for the free ligand was studied. All the data strongly suggest that trypanocidal action of the complexes could mainly rely on the inhibition of the parasite-specific enzyme NADH-fumarate reductase.

Abstract: The crystal structures of compounds Na[Cr(dipic)2] · 2H2O (1) and [Cr(dipic)(phen)Cl] · 1/2H2O (2), dipic = dipicolinate, phen = 1,10-phenantroline, were determined. In both complexes, Cr(III) is in a distorted octahedral environment. In complex (1), the metal is coordinated to two nearly perpendicular dipic anions acting as tridentate ligands through one oxygen of each carboxylate group and the pyridinic nitrogen atom. In complex (2), Cr(III) ion is similarly coordinated to a dipic anion, defining a ligand equatorial plane. The phen molecule bridges the remaining equatorial coordination site and one of the axial positions through its N-atoms. The other axial position is occupied by a chloride ion. The optimized geometries of both compounds and their corresponding harmonic vibrational frequencies were calculated using methods of density functional theory. The infrared, Raman and electronic spectra of the complexes were recorded. Assignments of the most characteristic bands are reported and discussed. Their electrochemical properties were also investigated. Both compounds exhibit similar redox behavior; they undergo two main reduction processes involving the metal center and the dipicolinato ligand. No Cr(III) oxidation processes were found.

Abstract: Ruthenium-based anticancer chemotherapies are making significant advances in clinical trials. Until recently, the focus has been on coordination complexes, and mechanisms such as "activation by reduction" and "transferrin-targeted delivery" have been proposed to account for the excellent cytotoxicity and low general toxicity of these complexes. More recently organoruthenium compounds, which to some extent appear not to follow the established rules, have started to be investigated. Despite such differences, similar activities between certain coordination and organometallic compounds suggest similar modes of action are present. DNA, the classic target, is believed to be the dominant mechanism for cytotoxicity with certain ruthenium drugs, while with others, non-classical targets are thought to be more important. In this article we describe these features and show how both ruthenium coordination complexes and organoruthenium compounds represent an ideal scaffold for further drug design and optimisation.

Abstract: The proposed curative properties of Cu-based non-steroidal anti-inflammatory drugs (NSAIDs) have led to the development of numerous Cu(II) complexes of NSAIDs with enhanced anti-inflammatory activity and reduced gastrointestinal (GI) toxicity compared with their uncomplexed parent drug. These low toxicity Cu drugs have yet to reach an extended human market, but are of enormous interest, because many of today's anti-inflammatory drug therapies, including those based on the NSAIDs, remain either largely inadequate and/or are associated with problematic renal, GI and cardiovascular side effects. The origins of the anti-inflammatory and gastric-sparing actions of Cu-NSAIDs, however, remain uncertain. Their ability to influence copper metabolism has been a matter of debate and, apart from their frequently reported superoxide dismutase (SOD)-like activity in vitro, relatively little is known about how they ultimately regulate the inflammatory process and/or immune system. Furthermore, little is known of their pharmacokinetic and biodistribution profile in both humans and animals, stability in biological media and pharmaceutical formulations, or the relative potency/efficacy of the Cu(II) monomeric versus Cu(II) dimeric complexes. The following review will not only discuss the etiology of inflammation, factors influencing the metabolism of copper and historical overview of the development of the Cu-NSAIDs, but also outline the structural characteristics, medicinal and veterinary properties, and proposed modes of action of the Cu-NSAIDs. It will also compare the SOD, anti-inflammatory and ulcerogenic effects of various Cu-NSAIDs. If the potential opportunities of the Cu-NSAIDs are to be completely realized, a mechanistic understanding and delineation of their in vivo and in vitro pharmacological activity is fundamental, along with further characterization of their pharmacokinetic/pharmacodynamic disposition.

Abstract: This review discusses the modes of coordination of oligopeptides by Cu(II) and Ni(II). Special attention is given to two general classes of peptides. The first part of the review deals with indirect effects introduced by special sequences of non-bonding side-chains. Unusual coordination modes resulting from the introduction of the break-point proline residues are also discussed. The second part of the review describes the binding properties of histidine peptides. The effects of the positioning of a His residue are discussed in the terms of cooperation and competition between potential metal anchoring sites. Special attention is given to His-3 peptides, modeling the biologically relevant albumin-like metal binding site. Finally, the coordination-related specific hydrolysis processes in histidine peptides are briefly discussed.

Abstract: This review provides an overview of metal-based anticancer drugs and drug candidates. In particular, we focus on metal complexes that can be activated in the reducing environment of cancer cells, thus serving as prodrugs. There are many reports of Pt and Ru complexes as redox-activatable drug candidates, but other d-block elements with variable oxidation states have a similar potential to serve as prodrugs in this manner. In this context are compounds based on Fe, Co, or Cu chemistry, which are also covered. A trend in the field of medicinal inorganic chemistry has been toward molecularly targeted, metal-based drugs obtained by functionalizing complexes with biologically active ligands. Another recent activity is the use of nanomaterials for drug delivery, exploiting passive targeting of tumors with nano-sized constructs made from Au, Fe, carbon, or organic polymers. Although complexes of all of the above mentioned metals will be described, this review focuses primarily on Pt compounds, including constructs containing nanomaterials.

Abstract: Vanadium is a transition metal that, being ubiquitously distributed in soil, crude oil, water and air, also found roles in biological systems and is an essential element in most living beings. There are also several groups of organisms which accumulate vanadium, employing it in their biological processes. Vanadium being a biological relevant element, it is not surprising that many vanadium based therapeutic drugs have been proposed for the treatment of several types of diseases. Namely, vanadium compounds, in particular organic derivatives, have been proposed for the treatment of diabetes, of cancer and of diseases caused by parasites. In this work we review the medicinal applications proposed for vanadium compounds with particular emphasis on the more recent publications. In cells, partly due to the similarity of vanadate and phosphate, vanadium compounds activate numerous signaling pathways and transcription factors; this by itself potentiates application of vanadium-based therapeutics. Nevertheless, this non-specific bio-activity may also introduce several deleterious side effects as in addition, due to Fenton's type reactions or of the reaction with atmospheric O2, VCs may also generate reactive oxygen species, thereby introducing oxidative stress with consequences presently not well evaluated, particularly for long-term administration of vanadium to humans. Notwithstanding, the potential of vanadium compounds to treat type 2 diabetes is still an open question and therapies using vanadium compounds for e.g. antitumor and anti-parasitic related diseases remain promising.