Design of a green chemoenzymatic cascade for scalable synthesis of bio-based styrene alternatives

TY - JOUR

T1 - Design of a green chemoenzymatic cascade for scalable synthesis of bio-based styrene alternatives

AU - Petermeier, Philipp

AU - Bittner, Jan Philipp

AU - Müller, Simon

AU - Byström, Emil

AU - Kara, Selin

PY - 2022/8/8

Y1 - 2022/8/8

N2 - As renewable lignin building blocks, hydroxystyrenes are particularly appealing as either a replacement or addition to styrene-based polymer chemistry. These monomers are obtained by decarboxylation of phenolic acids and often subjected to chemical modifications of their phenolic hydroxy groups to improve polymerization behaviour. Despite efforts, a simple, scalable, and purely (chemo)catalytic synthesis of acetylated hydroxystyrenes remains elusive. We thus propose a custom-made chemoenzymatic route that utilizes a phenolic acid decarboxylase (PAD). Our process development strategy encompasses a computational solvent assessment informing about solubilities and viable reactor operation modes, experimental solvent screening, cascade engineering, heterogenization of biocatalyst, tailoring of acetylation conditions, and reaction upscale in a rotating bed reactor. By this means, we established a clean one-pot two-step process that uses the renewable solvent CPME, bio-based phenolic acid educts and reusable immobilised PAD. The overall chemoenzymatic reaction cascade was demonstrated on a 1 L scale to yield 18.3 g 4-acetoxy-3-methoxystyrene in 96% isolated yield.

AB - As renewable lignin building blocks, hydroxystyrenes are particularly appealing as either a replacement or addition to styrene-based polymer chemistry. These monomers are obtained by decarboxylation of phenolic acids and often subjected to chemical modifications of their phenolic hydroxy groups to improve polymerization behaviour. Despite efforts, a simple, scalable, and purely (chemo)catalytic synthesis of acetylated hydroxystyrenes remains elusive. We thus propose a custom-made chemoenzymatic route that utilizes a phenolic acid decarboxylase (PAD). Our process development strategy encompasses a computational solvent assessment informing about solubilities and viable reactor operation modes, experimental solvent screening, cascade engineering, heterogenization of biocatalyst, tailoring of acetylation conditions, and reaction upscale in a rotating bed reactor. By this means, we established a clean one-pot two-step process that uses the renewable solvent CPME, bio-based phenolic acid educts and reusable immobilised PAD. The overall chemoenzymatic reaction cascade was demonstrated on a 1 L scale to yield 18.3 g 4-acetoxy-3-methoxystyrene in 96% isolated yield.

KW - CATECHOL

KW - CHEMISTRY

KW - CINNAMIC-ACIDS

KW - DECARBOXYLATION

KW - LIQUID-LIQUID EQUILIBRIA

KW - PLUS WATER

KW - POLYMERIZATION

KW - POLYMERS

KW - SOLUBILITY

KW - SOLVENTS

UR - http://www.scopus.com/inward/record.url?scp=85135712834&partnerID=8YFLogxK

U2 - 10.1039/d2gc01629j

DO - 10.1039/d2gc01629j

M3 - Journal article

SN - 1463-9262

VL - 24

SP - 6889

EP - 6899

JO - Green Chemistry

JF - Green Chemistry

IS - 18

ER -