Insights into the enzymatic synthesis of alcoholic flavor esters with molecular docking analysis

Abstract

The enzymatic synthesis is essential for the flavor esters in the food and fragrance industries. This paper introduces a novel preparation method for lipase microarrays (CALB@PMHOS-TEOS) with loadings up to 229 ± 1.4 mg/g. Using surfactant-free hydrophobic silica-hybridized mesoporous materials and Candida antarctica lipase, this resulted in the effective synthesis of flavor esters. Using CALB@PMHOS-TEOS a Pickering emulsion system was formed at the oil-water interface for the sustainable synthesis of flavor esters. This resulted in a 93.5 ± 0.5 % conversion of hexanoic acid within 2 h at an optimal temperature of 35 °C, which is the highest level recorded in the literature to date. Furthermore, the conversion of hexanoic acid was maintained at 63.9 ± 1.2 % after 9 cycles of CALB@PMHOS-TEOS reuse. The application of the enzyme to the synthesis in a variety of flavor esters achieved a new benchmark in the existing literature. A molecular docking model was evaluated to understand the molecular mechanism underpinning the immobilized lipase. This work introduces a novel method for the eco-friendly and efficient synthesis of flavor esters for applications across various fields including food and cosmetics.