Synthesis of organic-inorganic hybrid nanoflowers of lipases from Candida antarctica type B (CALB) and Thermomyces lanuginosus (TLL): Improvement of thermal stability and reusability.

Enzyme immobilization is used to improve the application of enzymes, allowing the reuse of biocatalysts and increasing their stability under reaction conditions. Immobilization of enzymes through structures, such as nanoflowers, is an innovative, simple, and low-cost method compared to other techniques. In this context, the main objective of this work is to synthesize hybrid biocatalytic nanostructures, similar to flowers, of lipases from Candida antarctica type B (CALB) and Thermomyces lanuginosus (TLL). The production of nanoflowers occurred by precipitation of lipases with CuCl2 or CuSO4 salts for 72 h. However, challenges and obstacles were faced in obtaining effective and practical nanoflowers, such as nanoflowers' low thermal stability and reusability. To overcome these challenges, two conditions were tested: nanoflowers cross-linked with glutaraldehyde and nanoflowers and nanoparticles cross-linked with glutaraldehyde. This last biocatalyst prepared by CuSO4 precipitation showed better thermal stability (half-life about 230 and 233 min for CALB and TLL, respectively, under incubation at 60 °C and pH 7). The CALB biocatalyst retained 70 % of its initial activity (2.31 U) after 10 cycles of hydrolysis. Therefore, this work shows not only the problems and barriers of nanoflowers synthesis, but also the possibility of producing more stable and efficient biocatalysts using improved protocols.

An overview on the conversion of glycerol to value-added industrial products via chemical and biochemical routes.

Glycerol is a common by-product of industrial biodiesel syntheses. Due to its properties, availability, and versatility, residual glycerol can be used as a raw material in the production of high value-added industrial inputs and outputs. In particular, products like hydrogen, propylene glycol, acrolein, epichlorohydrin, dioxalane and dioxane, glycerol carbonate, n-butanol, citric acid, ethanol, butanol, propionic acid, (mono-, di-, and triacylglycerols), cynamoil esters, glycerol acetate, benzoic acid, and other applications. In this context, the present study presents a critical evaluation of the innovative technologies based on the use of residual glycerol in different industries, including the pharmaceutical, textile, food, cosmetic, and energy sectors. Chemical and biochemical catalysts in the transformation of residual glycerol are explored, along with the factors to be considered regarding the choice of catalyst route used in the conversion process, aiming at improving the production of these industrial products.