Tuneable 3D printed bioreactors for transaminations under continuous-flow

Edgar Peris; Obinna Okafor; Evelina Kulcinskaja; Ruth Goodridge; Santiago V. Luis; Eduardo Garcia-Verdugo; Elaine O'Reilly; Victor Sans

doi:10.1039/C7GC02421E

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Tuneable 3D printed bioreactors for transaminations under continuous-flow

Edgar Peris, Obinna Okafor, Evelina Kulcinskaja, Ruth Goodridge, Santiago V. Luis, Eduardo Garcia-Verdugo, Elaine O'Reilly and Victor Sans
Green Chem., 2017,19, 5345-5349
DOI: 10.1039/C7GC02421E, Communication

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Abstract | Cited by

A method to efficiently immobilize enzymes on 3D printed continuous-flow devices is presented. Application of these chemically modified devices enables rapid screening of immobilization mechanisms and reaction conditions, simple transfer of optimised conditions into tailored printed microfluidic reactors and development of continuous-flow biocatalytic processes. The bioreactors showed good activity (8–20.5 μmol h⁻¹ mg_enz⁻¹) in the kinetic resolution of 1-methylbenzylamine, and very good stability (ca. 100 h under flow).

Graphical abstract: Tuneable 3D printed bioreactors for transaminations under continuous-flow

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