Journal
COLLOIDS AND SURFACES B-BIOINTERFACES
Volume 151, Issue -, Pages 88-94Publisher
ELSEVIER SCIENCE BV
DOI: 10.1016/j.colsurfb.2016.12.006
Keywords
Millifluidics; Laminar flow; Laccase; Hollow particles; CLEA
Funding
- Agency for Science, Technology and Research (A*STAR) in Singapore [1421200079]
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Hollow cross-linked enzyme aggregates of laccase (h-CLEA laccase) can be prepared by employing a millifluidic reactor carrying two coaxial laminar flows. In a confluence zone where acetonitrile and an aqueous solution of laccase meet, diffusion of acetonitrile into the aqueous solution gives rise to rapid precipitation of laccase aggregates at the water/acetonitrile interface, as is evidenced by fluorescence images. By controlling the flow rates carefully in the laminar flow regions, h-CLEA laccase around 220 +/- 10 nm can be obtained, and the size of the h-CLEA laccase increases with increasing flow rates of both solutions. The h-CLEA laccase particles are distinctly different from CLEA laccase prepared in batch processes. The former only consist a crust of cross-linked enzymes (with a hollow core) whereas the latter has a highly porous structure. When the h-CLEA laccase is used as biocatalysts, their activity (0.26 U/mg) is comparable to that of free enzymes at neutral pH due to the hollow structure. Moreover, the activity of h-CLEA laccase is higher than that of free laccase at high pH. For example, trypan blue (a dye molecule) can be decolorized completely in the presence of h-CLEA laccase within 270 min even at pH 10.0, at which the free enzyme completely loses its activity. Because of their uniform sizes, h-CLEA laccase can be trapped in a membrane for continuous degradation of trypan blue up to 96 h without losing any activity. This study shows the superiority of h-CLEA laccase compared to other types of immobilized enzymes. (C) 2016 Elsevier B.V. All rights reserved.
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