Singlet oxygenation in microemulsion catalysed by vanadium chloroperoxidase

Non-ionic microemulsions compatible with the enzyme vanadium chloroperoxidase were designed to perform singlet oxygenation of apolar substrates. The media were based on mono- and polydisperse ethoxylated fatty alcohols (C_iE_j), octane and aqueous buffer. “Fish” diagrams were determined to identify the Winsor-boundaries and to formulate a monophasic Winsor IV microemulsion with a minimal surfactant concentration, ensuring less singlet oxygen (¹O₂) loss than in an aqueous system, thus creating a high oxygenation efficiency. The enzyme was shown to be fully stable in the microemulsion for at least 10 h, converting H₂O₂ into a constant flow of ¹O₂ in the aqueous microdomains. Part of the ¹O₂ diffuses into the organic compartments prior to fast physical deactivation of ¹O₂ by water molecules. In the apolar domains ¹O₂ quantitatively converts the model substrate 9,10-dimethylanthracene into its corresponding endoperoxide. Near-IR chemiluminescence measurements confirm that the ¹O₂ signal in the microemulsion is higher than in simple aqueous buffer. In a well-stirred (water/octane) biphasic system endoperoxide formation is also observed but the conversion rate is much lower, most likely due to stronger physical quenching of ¹O₂.