Lipase Nanogel Catalyzed Transesterification in Anhydrous Dimethyl Sulfoxide

TL;DR: This manuscript conjugated an atom transfer radical polymerization (ATRP) initiator to acidic amino acid residues and lysine residues and grew polymers from Thermomyces lanuginosa lipase (TL), finding that the acidic residues are easily modified with multiple ATRP initiators and polymers are readily grown.

TL;DR: Pluronic-CALB conjugates were synthesized and characterized, exhibiting temperature-responsive properties and enhanced activity in organic solvents, with improved recovery and stability, making them suitable for industrial enzymatic synthesis in organic media.

TL;DR: Nanobiocatalysts are enzyme-loaded nanomaterials with high catalytic potential, efficiency, stability, reusability, and enhanced enzyme–substrate interaction.

TL;DR: Several nanobiocatalysts combining enzymes and nanocarriers are highlighted in this review, with the emphasis on the design, preparation, properties, and potential applications of nanoscale enzyme carriers and nanobiocentrealysts.

TL;DR: The technological utility of enzymes can be enhanced greatly by using them in organic solvents rather than their natural aqueous reaction media, and they have found numerous potential applications, some of which are already commercialized.

TL;DR: Lipases can catalyze several other processes in organic media including esterification, aminolysis, acyl exchange, thiotransesterification, and oximolysis; some of these reactions proceed to an appreciable extent only in nonaqueous solvents.

TL;DR: Porcine pancreatic lipase catalyzes the transesterification reaction between tributyrin and various primary and secondary alcohols in a 99 percent organic medium and exhibits a high catalytic activity at that temperature.

TL;DR: Recently reported approaches to improve the enzyme stability in various nanostructures such as nanoparticles, nanofibers, mesoporous materials, and single enzyme nanoparticles (SENs) are reviewed.