Author:
Jamil N,Man R C,Suhaimi S,Shaarani S M,Arshad Z I M.,Mudalip S K A,Sulaiman S Z
Abstract
Abstract
Cyclodextrin glucanotransferase (CGTase) is a multifunctional industrial enzyme which undergoes cyclization reaction to converts starch into cyclodextrin. Due to their potential properties, cyclodextrin has been discovered to have numerous application in food industries, pharmaceuticals, agriculture and environmental engineering. However, the instability of the enzyme during the reaction process result in the low production of cyclodextrin. Thus, enzyme immobilization process has been used to improve the enzyme stability in order to achieve high production of cyclodextrin. In this study, CGTase from Bacillus licheniformis was immobilized on polyvinylidene difluoride hollow fiber membrane via physical adsorption. The optimization of the immobilization parameters and the performance of the immobilized CGTase were investigated. The adsorption of CGTase on hollow fiber membrane was evaluated by fourier transform infrared spectroscopy. Response surface methodology was employed to optimize enzyme immobilization by manipulating the immobilization parameters of contact time (15-33 h), immobilization pH (pH 6-8) and immobilization temperature (20-30 °C) on the immobilization yield. The optimized immobilization conditions were 24 °C of immobilization temperature, pH 6.7 and 24 h of contact time, with 88.25% of immobilization yield. Immobilization of CGTase on the hollow fiber membrane was successfully optimized and about 4.6-fold increment of immobilization yield was achieved after the optimization process. The kinetic parameters of the immobilized CGTase were 9.42 mgml−1 h−1 and 9.99 mg ml−1 for V
max and K
m value, respectively. The kinetic studies revealed that the catalytic efficiency of the immobilized CGTase was similar to the free CGTase, demonstrated that upon the immobilization process, adsorption of CGTase on hollow fiber membrane does not cause structural changes to the enzyme. Hence, immobilization of CGTase on the hollow fiber membrane substantially improved the production of cyclodextrin and suggesting that the hollow fiber membrane appeared as a suitable support for the enzyme immobilization system.