Development and Evaluation of Organometallic Anticancer Drug Candidates

Azmanova, Maria T.

January 2022

There is an urgent need to find novel anticancer therapeutics with different mechanisms of action than platinum-containing drugs, particularly for patients who relapse after having been initially treated with a platinum-containing chemotherapy regimen. This chemoresistance phenomena, along with the serious side effects observed with cisplatin, have led research in Medicinal Inorganic Chemistry to using other precious metals for the design of novel anticancer therapeutics. This work reports on the synthesis and characterisation of a series of organometallic drug candidates based on ruthenium, osmium, rhodium, and iridium, followed by investigation of their cancer-inhibiting properties via in vitro and in vivo studies. The cytotoxicity of these complexes against various human cancer cell lines is presented, as well as preliminary studies on their possible modes of action, determined via gene expression studies, cell cycle and apoptosis analysis, reactive oxygen species detection and mitochondrial-membrane potential assays. In addition, to confirm the surprising absence of in vitro toxicity against normal cells exhibited by some compounds, studies on ex vivo/in vitro isolated human lymphocytes from healthy individuals, have been conducted. One lead molecule has been progressed to in vivo studies in mice and toxicity and efficacy were assessed with a series of assays including determination of the maximum tolerated dose and pharmacodynamic studies. Structural modifications of the lead molecule with water-soluble phosphines were subsequently undertaken, with the aim to improve the stability and solubility of the parent 16-electron specie, and evaluations of the biological activity of these novel complexes are presented.

Half-sandwich metal complexes

Electron-deficient organometallics

Bioinorganic chemistry

Anticancer metallodrugs

Anticancer therapeutics

Evaluation of the toxicity of two electron-deficient half-sandwich complexes against human lymphocytes from healthy individuals

Habas, Khaled S.A., Soldevila Barreda, Joan J., Azmanova, Maria, Rafols, Laia, Pitto-Barry, Anaïs, Anderson, Diana, Barry, Nicolas P.E.

29 October 2020

Yes / Electron‐deficient half‐sandwich complexes are a class of under‐studied organometallics with demonstrated potential as metallodrug candidates. The present study investigates the effect of two 16‐electron organoruthenium complexes ([( p‐ cym)Ru(benzene‐1,2‐dithiolato)] ( 1 ) and [( p ‐cym)Ru(maleonitriledithiolate)] ( 2 )) on the cell viability of non‐immortalised human lymphocytes from healthy individuals. The genotoxic effects of 1 and 2 in lymphocytes using the Comet and cytokinesis‐block micronucleus assays is also investigated. Gene expression studies were carried out on a panel of genes involved in apoptosis and DNA damage repair response. Results show that the two 16‐electron complexes do not have significant effect on the cell viability of human lymphocytes from healthy individuals. However, an increase in DNA damage is induced by both compounds, presumably through oxidative stress production. / This project was supported by the Royal Society (University Research Fellowship No. UF150295 to NPEB), the University of Bradford (RDF Award), and by the Academy of Medical Sciences/the Wellcome Trust/ the Government Department of Business, Energy and Industrial Strategy/ the British Heart Foundation Springboard Award [SBF003\1170 to NPEB].

Half-sandwich complexes

Electron-deficient organometallics

Bioinorganic chemistry

Lymphocytes

Anticancer metallodrugs

Targeted Delivery of Cytotoxic Metal Complexes into Cancer Cells with and without Macromolecular Vehicles

Mitra, Raja

January 2013

Anticancer active metal complexes such as cisplatin are routinely used for treating various cancers since 1978. However, the side effects of cisplatin overwhelm its therapeutic potential, especially in the latter stages of treatment. The nonspecific cytotoxicity of drugs could be avoided if targeted delivery to cancer cells is achieved using two different methodologies namely, enhanced permeability and retention in solid tumors (EPR) and receptor mediated endocytosis using a homing agent (RME). Ru(II)-arene complexes which are delivered specifically into cancer cells by the transferrin enzyme are less toxic compared to other metal complexes. The thesis describes the synthesis and use of Ru(II)-η6cymene complexes with different ancillary ligands which modulates the anticancer activity and the utility of two macromolecular vehicles in directed drug delivery. Ru(II)-η6cymene complexes with different heterocyclic ancillary ligands are synthesized and their anticancer activity tested against various cancer cell lines. Ruthenium complexes with mercaptobenzothiazoles are found to be quite active against the H460 cell lines that overexpress transferrin receptors and non-cytotoxic to the normal cell line, HEL299. Biophysical studies show that complexes (H1 and H8) can unwind the pBR322 DNA and inhibit the Topo IIα enzyme. A unique biphasic melting curve of CT DNA is observed in the presence of H1 which is attributed to formation of a dinuclear species (H20). Half-sandwich complexes of 6-thioguanine (6-TG) have also been prepared to improve the delivery and efficacy of 6-TG which is used in spite of a deleterious photoreaction. The Ru complexes cytotoxic to several leukemia cell lines. As they are photostable and anticancer active, they are better than 6-TG. Anticancer activity exhibiting piazselenols are used as ancillary ligands to make Ru(II)-arene complexes. Unfortunately, 1H NMR spectra suggests that piazselenol complexes dissociate in solution. However, the nitro substituted piazselenol and its Ru complex show the greatest cytotoxicity (<0.1 µM) against the A2780 cell line. The utility of PAMAM dendrimers and hyper branched polymers (hybramers) conjugated with a homing agent to target cancer cells by EPR and RME is probed. A cytotoxic copper complex (CuATSM) is covalently attached to the macromolecules through a disulfide linker, cleaved in the presence of GSH. Targeting efficacy of the folic acid-dendrimer conjugates is checked against two glioma cell lines. The folic acid-dendrimer conjugate is more active compared to dendrimer conjugate without folic acid against folate-receptor-overexpressing LN18 cell line. Biotin conjugated dendrimer shows better accumulation in HeLa cells, which require high amounts of biotin for growth. In vivo studies demonstrate that the conjugate can cross the blood-brain barrier. These studies suggest that PAMAM dendrimer can be used as a targeted delivery vehicle for cytotoxic metal complexes. Hyperbranched polymers decorated with propargyl groups and hydrophilic OH terminated TEG groups are attached to biotin and a cytotoxic Cu complex. (CuATSM-SS-CONH-N3) through ‘click’ reactions and tested against the HeLa cell line. On the basis of the studies conducted, it is concluded that targeted delivery of cytotoxic metal complexes are possible in the case of Ru(II) half-sandwich complexes and macromolecular vehicles like dendrimers are suitable for specifically delivering copper complexes into cancer cells.

Metal Complexes - Cancer Therapy

Targeted Drug Delivery

Metallodrugs

Chemotherapy

Anticancer Active Metal Complexes

Anticancer Metallodrugs

Cancer - Treatment

Targeted Therapy

Ru(II)-Heterocycle Complexes

Ru(II) Complexes

Cytotoxic Copper Complexes

Medicinal Chemistry