Engineering oxaliplatin(iv) prodrugs with monohaloacetates for redox-responsive and multimodal anticancer activity

A series of novel oxaliplatin(iv) complexes bearing monohaloacetic acids (MAAs) were synthesised to address the limitations of platinum-based chemotherapy related to severe side effects and resistance phenomena. Both symmetrical [Pt(DACH)(ox)(MAA)2] and asymmetrical [Pt(DACH)(ox)(MAA)(OAc)] derivatives featuring monofluoroacetate, monochloroacetate, or monobromoacetate were fully characterised (multi-nuclear NMR, elemental analysis) and evaluated for aqueous solubility, stability in DMSO and phosphate-buffered saline, and redox behaviour via cyclic voltammetry. Reduction assays with dithiothreitol confirmed efficient Pt(iv) → Pt(ii) conversion on timescales compatible with physiological conditions. Cytotoxicity studies on human ovarian carcinoma A2780 cells under normoxic and hypoxic environments highlighted increased activity under hypoxia, suggesting preferential prodrug activation in a reducing tumour-like milieu. Asymmetrical complexes generally offered improved solubility and promising antiproliferative profiles, whereas certain monobromoacetate-containing derivatives displayed partial instability linked to the higher leaving group ability of bromide. Notably, mechanistic investigations indicated that the enhanced cytotoxicity of selected bromoacetate-functionalised complexes is not associated with increased DNA damage relative to oxaliplatin, suggesting the contribution of additional non-genomic pathways. These findings emphasise the promise of monohaloacetate-functionalised oxaliplatin(iv) complexes as multimodal prodrugs combining platinum-mediated cytotoxicity with complementary bioactive mechanisms for improved anticancer efficacy.