Process sustainability of biocatalytic processes is significantly empowered with the use of continuous-flow technologies that offer high productivity, minimal wastes and low volumetric consumption. Combining microreactor design with 3D printing technology can broaden the engineering potentials. This work proposes a protocol to modify the surface of 3D-printed PLA scaffolds, based on chitosan deposition. Mimicking the concept of microplates, multi-well plates were designed to facilitate parameter testing. Immobilization of laccase from Trametes versicolor was successfully performed, while chitosan and cross-linker concentration and incubation time were optimized. Τhe developed protocol was applied for the continuous flow bioconversion of hydroxyyrosol, yielding a TTN of 438.6 × 103 for a total of 10 h continuous use. Also, a peristaltic flow pattern seemed to favor the system performance, reaching 95% bioconversion efficiency in a total of 1 h reaction time. The potential of the developed system was further evaluated for the biotransformation of different biophenols from dietary sources, proving the efficiency of the system as a versatile biotechnological tool.
Keywords: 3D printing; Biophenols; Continuous flow biocatalysis; Laccase; Microreactor.
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