Carbon Nanotube PtSn Nanoparticles for Enhanced Complete Biocatalytic Oxidation of Ethylene Glycol in Biofuel Cells

[Image: see text] We report a hybrid catalytic system containing metallic PtSn nanoparticles deposited on multiwalled carbon nanotubes (Pt(65)Sn(35)/MWCNTs), prepared by the microwave-assisted method, coupled to the enzyme oxalate oxidase (OxOx) for complete ethylene glycol (EG) electrooxidation. Pt(65)Sn(35)/MWCNTs, without OxOx, showed good electrochemical activity toward EG oxidation and all the byproducts. Pt(65)Sn(35)/MWCNTs cleaved the glyoxilic acid C–C bond, producing CO(2) and formic acid, which was further oxidized at the electrode. Concerning EG oxidation, the catalytic activity of the hybrid system (Pt(65)Sn(35)/MWCNTs+OxOx) was twice the catalytic activity of Pt(65)Sn(35)/MWCNTs. Long-term electrolysis revealed that Pt(65)Sn(35)/MWCNTs+OxOx was much more active for EG oxidation than Pt(65)Sn(35)/MWCNTs: the charge increased by 65%. The chromatographic results proved that Pt(65)Sn(35)/MWCNTs+OxOx collected all of the 10 electrons per molecule of the fuel and was able to catalyze EG oxidation to CO(2) due to the associative oxidation between the metallic nanoparticles and the enzymatic pathway. Overall, Pt(65)Sn(35)/MWCNTs+OxOx proved to be a promising system to enhance the development of enzymatic biofuel cells for further application in the bioelectrochemistry field.