Lipase Catalyzed HEMA Initiated Ring-Opening Polymerization: In Situ Formation of Mixed Polyester Methacrylates by Transesterification

Takwa, Mohamad; Xiao, Yan; Simpson, Neil; Malmström, Eva; Hult, Karl; Koning, Cor E.; Heise, Andreas; Martinelle, Mats

doi:10.1021/bm7010449

Cited by 49 publications

(53 citation statements)

References 35 publications

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“…perform reactions under equilibrium conditions), allows high endgroup fidelity in a lipase-catalyzed ROP, even in a one-pot procedure [58,80,111,112,[116][117][118]. Initiation with mercapto-ethanol or 6-mercapto-1-hexanol in lipasecatalyzed ROP of CL and ω-pentadecanolactone (PDL), respectively, resulted in high initiator incorporation (95%).…”

Section: Endgroup Fidelity In Lipase-catalyzed Rop Of Lactonesmentioning

confidence: 99%

Hydrolases Part I: Enzyme Mechanism, Selectivity and Control in the Synthesis of Well-Defined Polymers

Veld

Palmans

2010

Advances in Polymer Science

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Lipases are highly activity in the polymerization of a range of monomers. Both ring-opening polymerization of cyclic esters and polycondensation reactions of AA-BB and AB monomers have been investigated in great detail. This paper reviews the increased understanding in enzymatic strategies for the production of well-defined polymers. Major advantages of enzymatic catalysts are the relatively mild reaction conditions, and the often-observed excellent regio-, chemo-, and enantioselectivity that allow for the direct preparation of functional materials. However, as a result of the monomer activation mechanism, polymers of low polydispersity and low quantitative degree of endgroup functionality are difficult to attain. A wide variety of (co)polymers have been synthesized and explored in a variety of applications using lipase catalysts.

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Section: Endgroup Fidelity In Lipase-catalyzed Rop Of Lactonesmentioning

confidence: 99%

Hydrolases Part I: Enzyme Mechanism, Selectivity and Control in the Synthesis of Well-Defined Polymers

Veld

Palmans

2010

Advances in Polymer Science

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“…This is in full analogy with the processes found when using HEMA as the initiator. [26] In lipase catalysis, a covalent intermediate, acyl enzyme, is formed by nucleophilic attack on the carbonyl carbon (in the ester to be cleaved) by the active nucleophile (serine) situated at the active site of the enzyme. In Scheme 1, three different acyl enzymes are illustrated: (A) lipase acylated by the opened monomer; (B) lipase acylated by the (meth)acrylate moiety; (C) lipase acylated by a polyester moiety.…”

Section: Polyester Structuresmentioning

confidence: 99%

“…In a recent study we were able to show that in the HEMA-initiated ROP of PDL and CL, the ester bond within the HEMA participates in the transesterification reactions, resulting in a mixture of polymer products with various end-groups, such as polymers with no, with one and with two methacrylate end-groups. [26] Furthermore, the 1,2-ethanediol moiety (from HEMA) was found within the polyester chains. The extent and thus the distribution of the end-groups were found to depend on the reaction time and the monomer used.…”

Section: Introductionmentioning

confidence: 99%

Systematic Comparison of HEA and HEMA as Initiators in Enzymatic Ring‐Opening Polymerizations

Xiao¹,

Takwa²,

Hult³

et al. 2009

Macromolecular Bioscience

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Two initiators containing a cleavable ester bond were compared in the lipase-catalyzed ROP of CL and PDL. The results show that transesterification reactions are present at high rates throughout the enzymatic ROP and start at low conversion. HEA and HEMA displayed similar reaction efficiencies as initiators (acyl acceptors) in the enzymatic ROP. However, transacylation reactions on the HEA-initiated polyesters were found to be 15 times faster. While in both cases the amount of HEA- and HEMA-initiated polymers could be maximized by short reaction times, a well-defined (meth)acrylation by this approach was not possible. Our results show that transesterification reactions have to be considered when performing an enzyme-catalyzed ROP.

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“…Recently, oligomers of PPDL were obtained at 70 and 90 °C for 24 h [84]. PPDL can be also synthesized in the presence of HEMA initiator [85], in order to obtain methacrylated aliphatic polyester, which in further studies can be used for formation of macroporous matrices for tissue scaffolds [86]. Another difunctional poly(ω-PDL) designed for biomedical application was prepared by solvent free ROP of PDL in the presence of 4 wt% of N-435 and initiated by 6-mercapto-1-hexanol and terminated by γ-thiobutyrolactone or vinyl acrylate (Scheme 4e) [87].…”

mentioning

confidence: 99%

Candida antarctica Lipase B as Catalyst for Cyclic Esters Synthesis, Their Polymerization and Degradation of Aliphatic Polyesters

et al. 2017

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Lipase Catalyzed HEMA Initiated Ring-Opening Polymerization: In Situ Formation of Mixed Polyester Methacrylates by Transesterification

Cited by 49 publications

References 35 publications

Hydrolases Part I: Enzyme Mechanism, Selectivity and Control in the Synthesis of Well-Defined Polymers

Hydrolases Part I: Enzyme Mechanism, Selectivity and Control in the Synthesis of Well-Defined Polymers

Systematic Comparison of HEA and HEMA as Initiators in Enzymatic Ring‐Opening Polymerizations

Candida antarctica Lipase B as Catalyst for Cyclic Esters Synthesis, Their Polymerization and Degradation of Aliphatic Polyesters

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