Magnetic Halloysite Nanotube/α-Amylase Based Nanobiocatalytic Transformation of Food Processing Waste into an Active Fermentation Ingredient

Abstract

The concept of “nanobiocatalysis” creates exciting opportunities for improving enzyme performance via immobilization onto nanomaterials. A nanobiocatalyst consisting of magnetic halloysite nanotube (MHNT)/α-amylase was evaluated to transform food processing waste into an active fermentation medium formulation for low-cost bioprocessing. A high loading of α-amylase (185.5 mg (g of support)−1) was achieved on the surface of MHNTs through polydopamine functionalization. We validated the establishment of an enzyme-support system retaining >89% catalytic activity (27332 IU (g of support)−1) with improved enzyme handling (>99.1% recovery) and reusability (>56% activity, 10 cycles). MHNTs remarkably improved the enzyme kinetics and thermodynamic characteristics along with operational and storage stabilities and mitigated the likely inhibitory effects of cellulose/metal ions as contaminants. In addition to facilitating a continuous production of reducing sugars from the extracted starch over 72 h, the nanobiocatalyst was equally effective in preparing a nutritive food waste hydrolysate as a fermentable medium substitute for batch culturing of E. coli and a single-cell protein (A. niger). The commercial relevance of waste hydrolysate was also investigated to promote calcite precipitation via Bacillus sp. induced biocementation. We evidenced that nanobiocatalyst-assisted “starch depolymerization” released more nutritional components into the hydrolysate suspension, easily accessible to growing microbial cultures.