Insight into the synergistic effects of surface microstructures and wall peristalsis on glucose production in a bionic microreactor

Abstract

The enzymatic hydrolysis stage is regarded as a key step in the production of biofuels derived from lignocellulosic biomass, but the elevated production expenses and limited conversion efficiency are still not favorable for practical applications. In this study, inspired by the efficient degradation of cellulose in the termite gut, a cellulase-loaded flexible microreactor model with bionic surface structures was first proposed for the production of fermentable glucose. In such a system, the fold-like structures can provide more enzyme loading sites, and villus-like structures can not only increase enzyme loading but also improve radial transfer in the microreactor. These two structures synergized well and resulted in a 58.5% increase in glucose production compared to the control. Applying peristalsis can further enhance mass transfer by the formation of backflow and vortex, and reducing the peristaltic period is more effective than increasing the peristaltic amplitude for glucose production enhancement. The glucose concentration obtained by the synergistic enhancement of peristalsis and surface structure was 2.3 times of the control. Moreover, for reactions with higher intrinsic reaction rates, the system is in a mass transfer-limited state and peristaltic enhancement is more effective. These results give insight into the design of the bionic flexible microreactor for efficient glucose production.