Electrochemistry of conjugated planar anticancer molecules: Irinotecan and Sunitinib

The evaluation of drug levels is important for personalized therapeutic approaches particularly in cancer care. To this end electrochemistry provides simplicity, low cost, high sensitivity and possibility of miniaturization. Here we report the electrochemistry and UV-visible spectroscopy of two extensively used planar conjugated anticancer molecules, Irinotecan (ITC) and Sunitinib (SUN), in aprotic medium and water. Comparison is made with model compounds without amine ends. The electronic spectra of ITC and SUN in dimethylsulfoxide show similar vibronic patterns (0.2 eV vibrational energy for both) with energy gaps of 3.1 and 2.5 eV respectively. Cyclic voltammetry in acetonitrile shows the same oneelectron reduction peak (-1.9 V vs Ag/Ag+) and oxidation peaks at 1.45 and 0.65 V, both beyond the oxidation of the amine ends (0.45 V). In water the optical energy gaps are unchanged but the vibronic structure is almost lost and the oxidation processes are eased by 0.45 V for SUN and 1.10 V for ITC. The number of oxidatively exchanged electrons in water is two for ITC but four in two subsequent twoelectron steps for SUN. The overall oxidation process for ITC likely involves the nucleophilic attack of a water molecule to the quinoline moiety. The first two-electron oxidation of SUN, involving the pyrrole moiety, leads possibly to the conjugated imine ring which is further oxidized to the N-oxide form. Lowering of the electron-transfer activation energy by water is assigned in part to release of molecular rigidity but in ITC the major role is assigned to a nucleophilic attack of water already in the activated state.