The oxidation of the reduced flavin in choline oxidase was investigated with pH, solvent viscosity, and kinetic isotope effects (KIEs) in steady-state kinetics and time-resolved absorbance spectroscopy of the oxidative half-reaction in a stopped-flow spectrophotometer. Both the effects of isotopic substitution on the KIEs and the multiple KIEs suggest a mechanism for flavin oxidation in which the H atom from the reduced flavin and a H(+) from the solvent or a solvent exchangeable site are transferred in the same kinetic step. Stopped-flow kinetic data demonstrate flavin oxidation without stabilization of flavin-derived species. Solvent viscosity effects establish an isomerization of the reduced enzyme. These results allow us to rule out mechanisms for flavin oxidation in which C4a-peroxy and -hydroperoxy flavin intermediates accumulate to detectable levels in the reaction of flavin oxidation catalyzed by choline oxidase. A mechanism of flavin oxidation that directly results in the formation of oxidized flavin and hydrogen peroxide without stabilization of reaction intermediates is consistent with the data presented.