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Journal of Porous Materials

, Volume 26, Issue 1, pp 77–89 | Cite as

Immobilization of the enzyme invertase in SBA-15 with surfaces functionalized by different organic compounds

  • Livia M. O. RibeiroEmail author
  • Larissa N. S. S. Falleiros
  • Miriam M. de Resende
  • Eloízio J. Ribeiro
  • Renata M. R. G. Almeida
  • Antonio O. S. da Silva
Article
  • 93 Downloads

Abstract

The search for appropriate supports for enzyme immobilization has attracted increasing interest in the field of biocatalysis. Immobilized enzymes are catalysts of enormous industrial interest because they combine the advantages of heterogeneous catalysis with the high selectivity and mild operational conditions of enzymes. This study evaluated the use of different organic molecules as functionalizing agents anchored on the silanol groups present on the surface of mesoporous materials such as SBA-15. This modification aims to increase the interaction of the enzyme invertase to the support, allowing for a greater amount of this biocatalyst to be immobilized. The hexagonal mesoporous material SBA-15, which has pores in the range of 40–60 Å, was synthesized and modified by the following organic compounds: trimethoxyphenylsilane, vinyltrimethoxysilane and 3-aminopropyltriethoxysilane (APTES). APTES showed the best results in increasing the anchoring of enzymes on the material’s surface, providing a specific amount of enzyme loaded onto the surface of approximately 80% and, thus, showing successful functionalization.

Keywords

SBA-15 Silanes Functionalization Invertase Immobilization 

Notes

Acknowledgements

The authors acknowledge the support from the CAPES and CNPQ.

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Copyright information

© Springer Science+Business Media, LLC, part of Springer Nature 2018

Authors and Affiliations

  • Livia M. O. Ribeiro
    • 1
    Email author
  • Larissa N. S. S. Falleiros
    • 2
  • Miriam M. de Resende
    • 2
  • Eloízio J. Ribeiro
    • 2
  • Renata M. R. G. Almeida
    • 1
  • Antonio O. S. da Silva
    • 1
  1. 1.Federal University of AlagoasMaceióBrazil
  2. 2.Faculty of Chemical EngineeringUberlândia Federal UniversityUberlândiaBrazil

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