AI Article Synopsis
- * The study explored 12 hydrophilic and 22 hydrophobic deep eutectic solvents (DESs) to enhance the synthesis of glucose esters, finding that d,l-menthol-based DESs achieved a high yield of 92.85%.
- * New DESs based on cyclohexanone were developed, resulting in an even higher yield of 98.85%, and a method called the substrate anchoring index was introduced to evaluate and design more effective solvents.
Article Abstract
Glucose esters, heralded for their emulsifying and solubilizing properties, have found increasing application in food, pharmaceutical, and cosmetic sectors. However, the environmental impact of chemical synthesis and the problem of enzyme inactivation in enzymatic synthesis have hindered their application. To this end, deep eutectic solvents (DESs) with stabilized enzyme activity and better solubility properties are considered a promising solution. In the study, 12 kinds of hydrophilic DESs and 22 kinds of hydrophobic DESs were screened, and we examined their efficiency in the synthesis of glucose esters. The results indicated that d,l-menthol-based DESs have excellent performance, with the highest yield of 92.85%. The molecular dynamics simulations suggested that it can be attributed to DESs changing the size of substrate binding pocket, which in turn affects the substrate anchoring ability and the catalytic efficiency of lipase. To further evaluate the effects of the solvent on the substrate anchoring ability of enzymes, a novel strategy, namely, substrate anchoring index, which is based on the stability of the tetrahedral intermediate, was proposed and used for the designing of more efficient DESs. Fortunately, novel DESs based on cyclohexanone (menthol analogues) were successfully developed with a yield of 98.85%.
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| http://dx.doi.org/10.1021/acs.jafc.4c06877 | DOI Listing |
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