Selective Functionalization of In2O3 Nanowire Mat Devices for Biosensing Applications

Abstract

A strategy to covalently attach biological molecules to the electrochemically active surface of indium oxide nanowire (In₂O₃ NW) mat devices is presented. A self-assembled monolayer (SAM) of 4-(1,4-dihydroxybenzene)butyl phosphonic acid (HQ-PA) was generated on an indium tin oxide (ITO)-coated glass and In₂O₃ NWs surface. The chemical steps required for surface derivatization were optimized on an ITO surface prior to modifying the In₂O₃ NWs. The hydroquinone group contained in the HQ-PA SAM was electrochemically oxidized to quinone (Q-PA) at +330 mV. The monolayer of Q-PA was allowed to react with a thiol-terminated DNA. The DNA was paired to its complementary strand tagged with a fluorescence dye. Attachment of DNA was verified using fluorescence microscopy. A device was subsequently prepared on a SiO₂-supported mat of In₂O₃ NWs by depositing gold electrodes on the mat surface. The reaction strategy optimized on ITO was applied to this In₂O₃ NW-based device. Arrays of In₂O₃ NWs on a single substrate were electrochemically activated in a selective manner to Q-PA. Activated In₂O₃ NWs underwent reaction with HS-DNA and gave a positive fluorescence response after pairing with the dye-DNA. The unactivated In₂O₃ NWs gave no response, thus demonstrating selective functionalization of an In₂O₃ NW array. This can be considered a key step for the future fabrication of large-scale, inexpensive, nanoscale biosensors.