To obtain materials useful for the biomedical field, toxic catalysts should be removed from the synthetic route of polymerization reactions and of their precursors. Lipase-catalyzed ring-opening polymerization and the synthesis of cyclic precursors can be performed with the same catalyst under different conditions. Here, we highlight the use of lipases as catalysts and optimization of their performance for both ring-closing and ring-opening polymerization, via varying parameters such as ring size, concentration, substrate molar ratio, temperature, and solvent. While the conditions for ring-closing reactions and ring-opening polymerizations of small molecules, such as ε-caprolactone, have been extensively explored using Candida antarctica lipase B (CALB), the optimization of macrocyclization, especially for more bulky substrates is surveyed here. Finally, recent methods and polymer architectures are summarized with an emphasis on new procedures for more sustainable chemistry, such as the use of ionic liquids as solvents and recycling of polyesters by enzymatic pathways.
Polyesters are known biodegradable materials that are frequently used for biomedical applications that require biocompatibility. Their synthesis usually requires transition metal catalysts, which may become a source of contamination. In addition, using such compounds translates to extensive purification procedures, which do not agree with green chemistry principles. In addition to being renewable, enzymes such as lipases are milder for biological systems, and were studied for both ring-closure and ring-opening reactions. Here, Candida antarctica lipase B was used in ring-closure, reducing a two-step synthesis to a single step with 58% yield. The bile acid-containing macrocycles were subsequently polymerized with the same enzyme; relatively high molar masses (40 000 g/mol) were obtained. The conditions for the enzymatic ring-closure and ring-opening reactions were established through the reaction of thapsic acid with 1,10-decanediol. The di- and tetralactones afforded semicrystalline polymers with relatively high molar masses. Therefore, lipases were successfully used for both ring-closing reactions and ring-opening polymerizations of large rigid moieties as well as more flexible structures. The use of enzymes for the multistep syntheses shows their utility as a simple and green method for monomer and polymer synthesis with better biocompatibility and tunable properties.
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