Bioconjugation Strategy for Ceramic Membranes Decorated with Candida Antarctica Lipase B-Impact of Immobilization Process on Material Features

Enhanced catalytic performance of Candida rugosa lipase through immobilization on zirconium-2-methylimidazole: A novel biocatalyst approach

Immobilization of enzymes on suitable supports is a critical approach for enhancing enzyme stability, reusability, and overall catalytic efficiency. This study explores the immobilization of Candida rugosa lipase on zirconium-based 2-methylimidazole (ZrMI) nanoparticles, aiming to develop a stable and reusable biocatalyst. The ZrMI was produced via a solvothermal technique and analyzed using various characterization methods. Candida rugose lipase was immobilized using cross-linking agents, achieving an 87 % immobilization efficiency. The immobilized enzyme exhibited significantly enhanced thermal stability, broader pH tolerance, and increased catalytic efficiency compared to free C. rugose lipase. The ZrMI@lipase retained 69 % of its enzymatic activity following a 60-day storage period at 4 °C. Notably, it displayed significant reusability, maintaining 65 % of its original activity after undergoing 15 catalytic cycles. Examination of the kinetics revealed that the immobilized enzyme possessed a heightened substrate affinity (Km of 4.1 mM) and maximal reaction rate (Vmax of 85.7 μmol/ml/min) in comparison to the free enzyme (Km of 5.4 mM and Vmax of 69 μmol/ml/min), indicating enhanced catalytic efficiency. Validation through zeta potential and hydrodynamic size assessments verified the successful binding of the enzyme and the consistent colloidal characteristics. These results suggest that ZrMI is a promising support for C. rugose lipase immobilization, offering improved stability and reusability for various industrial applications. The study highlights the potential of ZrMI@lipase as an efficient and durable biocatalyst, contributing to advancements in enzyme immobilization technology and sustainable industrial processes.

Pros and Cons in Various Immobilization Techniques and Carriers for Enzymes

In recent years, enzyme immobilization technology has been developed, and studies on immobilized enzyme materials have become very prominent. With the immobilization technique, enzymes and compatible carrier materials are combined or enzyme crystals/aggregates are used in a carrier-free fashion, by physical, chemical, or biochemical methods. As a kind of biocatalyst, immobilized enzymes can catalyze certain chemical reactions with high selectivity and high efficiency under relatively mild reaction conditions and eliminate pollution to the environment. Considering the current status and applications of immobilized enzyme technology and materials emerging in the last 5 years, this mini-review introduces the advantages and disadvantages of various enzyme immobilization techniques with carriers as well as the pros and cons of different materials for immobilization. The future prospects of immobilization technology and carrier materials are outlined, aiming to provide a reference for further research and applications of sustainable technology.