The approved platinum(II)-based anticancer agents cisplatin, carboplatin and oxaliplatin are widely utilised in the clinic, although with numerous disadvantages. With the aim of circumventing unwanted side-effects, a great deal of research is being conducted in the areas of cancer-specific targeting, drug administration and drug delivery. The targeting of platinum complexes to cancerous tissues can be achieved by the attachment of small molecules with biological significance. In addition, the administration of platinum complexes in the form of platinum(IV) allows for intracellular reduction to release the active form of the drug, cisplatin. Drug delivery includes such technologies as liposomes, dendrimers, polymers and nanotubes, with all showing promise for the delivery of platinum compounds. In this paper we highlight some of the recent advances in the field of platinum chemotherapeutics, with a focus on the technologies that attempt to utilise the cytotoxic nature of cisplatin, whilst improving drug targeting to reduce side-effects.
With an ageing baby-boomer population in the Western World, cancer is becoming a significant cause of death. The prevalence of cancer and all associated costs, both in human and financial terms, drives the search for new therapeutic drugs and treatments. Platinum anticancer agents, such as cisplatin have been highly successful but there are several disadvantages associated with their use. What is need are new compounds with different mechanisms of action and resistance profiles. What needs to be recognised is that there are many other metal in the periodic table with therapeutic potential. Here we have highlighted metal complexes with activity and have illustrate the different approaches to the design of anticancer complexes.
This report describes the synthesis, characterization and biological activity of a series of platinum(iv) derivatives of [Pt(1S,2S-DACH)(5,6-dimethyl-1,10-phenanthroline)] (Pt56MeSS) with non-bioactive, lipophilic and bioactive axial ligands. In an attempt to explore the anticancer activity potential of the Pt(iv) derivatives, 2D and 3D cytotoxic screening and a preliminary in vivo study were performed. The average IC values of the platinum(iv) derivatives ranged from 1.26 to 5.39 μM, compared with 1.24 μM for Pt56MeSS, suggesting that the axial ligands have a relatively minor effect on the potency of the compounds. Preliminary in vivo studies indicate that the platinum(iv) derivatives of Pt56MeSS are active in vivo and can reduce the tumor to a similar extent to cisplatin.
these results suggest that 56MESS is capable of causing cell-cycle arrest, and that mitochondrial and cell cycle proteins may be involved in the mode of action of cytotoxicity of 56MESS.
Four dinuclear terpyridineplatinum(II) (Pt-terpy) complexes were investigated for interactions with G-quadruplex DNA (QDNA) and duplex DNA (dsDNA) by synchrotron radiation circular dichroism (SRCD), fluorescent intercalator displacement (FID) assays and fluorescence resonance energy transfer (FRET) melting studies. Additionally, computational docking studies were undertaken to provide insight into potential binding modes for these complexes. The complexes demonstrated the ability to increase the melting temperature of various QDNA motifs by up to 17 °C and maintain this in up to a 600-fold excess of dsDNA. This study demonstrates that dinuclear Pt-terpy complexes stabilise QDNA and have a high degree of selectivity for QDNA over dsDNA.
Dinuclear (2,2':6',2''-terpyridine)platinum(II) (PtTerpy) complexes were synthesised by tethering either thiol or pyridine based linkers. All intermediates and resulting complexes were characterised using a combination of (1)H and (195)Pt NMR, two-dimensional (1)H correlation spectroscopy (NOSY/COSY), two-dimensional (1)H/(195)Pt heteronuclear multiple bond correlation spectroscopy (HMQC), elemental analysis and electrospray ionisation mass spectrometry (ESI-MS). The cytotoxicity of the complexes was determined against human A2780 ovarian carcinoma cells and its cisplatin-resistant sub-line A2780cis, as well as L1210 murine leukemia cells.
With current chemotherapeutic treatment regimes often limited by adverse side effects, the synergistic combination of complexes with anticancer activity appears to offer a promising strategy for effective cancer treatment. This work investigates the anti-proliferative activity using a combination therapy approach where metallointercalators of the type [Pt(IL)(AL)](2+) (where IL is the intercalating ligand and AL is the ancillary ligand) are used in combination with currently approved anticancer drugs cisplatin and carboplatin and organic molecules buthionine-S,R-sulfoximine and 3-bromopyruvate. Synergistic relationships were observed, indicating a potential to decrease dose-dependent toxicity and improve therapeutic efficacy.
Deoxyribonucleic acid is generally accepted as the primary biomolecular target of the first platinum-based chemotherapeutic agent, cisplatin, which was documented in 1845, characterised in 1893 and its potential discovered in 1965. Initial attempts to understand the structural significance of the compound by combinatorial means saw early conceptions of structure–activity relationships that were soon challenged. Almost 50 years and thousands of complexes later, DNA still remains the primary target in a variety of interactions ranging from differences in base-pair preference, irreversible covalent binding, and reversible minor/major groove binding and intercalation. Developmental efforts have seen active cytotoxic platinum complexes with structures derived beyond initial assumptions through a diversity of ligand substitution and multinuclear linkages. Nonetheless nephrotoxicity and neurotoxicity pose as dire inherent side-effects in clinical trials and application of platinum therapeutics. Subsequent development has called for means to avoid diminished efficacy due to inactivation by endogenous glutathione and other complex-binding or chelating proteins. Platinum(IV) derivatives may solve issues of unintended toxicity by means of intrinsic extracellular stability, degrading to their active platinum(II) forms once internalised within a cytosol and in acidic tumour environments. Selectivity may also be gained by the axial/apical coordination of ligands that typically bind to receptors that are overexpressed in certain tumours, such as modified-estrogen ligands. The development of platinum complexes has required an in-depth understanding of their DNA-binding interactions in order to facilitate further structural modification without loss of effective function for their eventual application as chemotherapeutics. Although platinum complexes are the focus of this chapter, some other metal complexes that interact with nucleic acids, such as ruthenium, iridium, osmium, iron, copper, titanium, vanadium gold and silver, are discussed.
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