Enzymatic Synthesis of Ascorbyl Palmitate in a Rotating Bed Reactor.

Ascorbyl palmitate, an ascorbic acid ester, is an important amphipathic antioxidant that has several applications in foods, pharmaceuticals, and cosmetics. The enzymatic synthesis of ascorbyl palmitate is very attractive, but few efforts have been made to address its process scale-up and implementation. This study aimed at evaluating the enzymatic synthesis of ascorbyl palmitate in a rotating basket reactor operated in sequential batches. Different commercial immobilized lipases were tested, and the most suitable reaction conditions were established. Among those lipases studied were Amano Lipase PS, Lipozyme® TL IM, Lipozyme® Novo 40086, Lipozyme® RM IM and Lipozyme® 435. Initially, the enzymes were screened based on previously defined synthesis conditions, showing clear differences in behavior. Lipozyme® 435 proved to be the best catalyst, reaching the highest values of initial reaction rate and yield. Therefore, it was selected for the following studies. Among the solvents assayed, 2-methyl-2-butanol and acetone showed the highest yields, but the operational stability of the catalyst was better in 2-methyl-2-butanol. The tests in a basket reactor showed great potential for large-scale application. Yields remained over 80% after four sequential batches, and the basket allowed for easy catalyst recycling. The results obtained in basket reactor are certainly a contribution to the enzymatic synthesis of ascorbyl palmitate as a competitive alternative to chemical synthesis. This may inspire future cost-effectiveness studies of the process to assess its potential as a viable alternative to be implemented.

Development of a Hybrid Bioinorganic Nanobiocatalyst: Remarkable Impact of the Immobilization Conditions on Activity and Stability of ß-Galactosidase.

Hybrid bioinorganic biocatalysts have received much attention due to their simple synthesis, high efficiency, and structural features that favor enzyme activity and stability. The present work introduces a biomineralization strategy for the formation of hybrid nanocrystals from ß-galactosidase. The effects of the immobilization conditions were studied, identifying the important effect of metal ions and pH on the immobilization yield and the recovered activity. For a deeper understanding of the biomineralization process, an in silico study was carried out to identify the ion binding sites at the different conditions. The selected ß-galactosidase nanocrystals showed high specific activity (35,000 IU/g biocatalyst) and remarkable thermal stability with a half-life 11 times higher than the soluble enzyme. The nanobiocatalyst was successfully tested for the synthesis of galacto-oligosaccharides, achieving an outstanding performance, showing no signs of diffusional limitations. Thus, a new, simple, biocompatible and inexpensive nanobiocatalyst was produced with high enzyme recovery (82%), exhibiting high specific activity and high stability, with promising industrial applications.

Entrapment of enzyme aggregates in chitosan beads for aroma release in white wines.

Glycosidases are enzymes involved in the cascade reactions leading to the release of aromatic compounds in white wines. However, the use of commercial soluble glycosidases is facing difficulties due to their fast inactivation, poor reaction control, low efficiency of enzyme use, and the presence of catalyst residues in the product. Co-immobilization as cross-linked enzyme aggregates (combi-CLEAs) is a sound alternative allowing the immobilization of enzymes in their own protein matrix, yielding highly stable and active biocatalysts. Notwithstanding, their micrometer sized particles limit their application in industrial processes. To overcome this, combi-CLEAs of ß-D-glucosidase (ßG) and α-L-arabinofuranosidase (ARA) were entrapped in polymeric chitosan beads. The effect of crosslinking reagents and crosslinking time on the specific activity and stability of combi-CLEAs was studied, and the best conditions for the entrapment of the combi-CLEAs in polymeric chitosan beads were determined varying the concentration of the chitosan solution and the pH of the gelation agent solution. The resulting biocatalyst beads (average diameter 1.24 mm), retained full activity after 91 days of incubation under winemaking conditions, having specific activities of 0.91 and 0.88 international units of activity per gram for ßG and ARA, respectively. Such characteristics make them suitable for aroma enhancement in wines.