Immobilization of urease in ZnAl Layered Double Hydroxides by soft chemistry routes

Immobilization of urease in Zn RAl layered double hydroxides is realized in order to develop novel urea biosensors for medical diagnosis and continuous monitoring devices for the environment. Different soft chemistry preparation methods are tested and compared. Adsorption isotherms of urease on ZnAl...

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Published inMicroporous and mesoporous materials Vol. 107; no. 1; pp. 190 - 201
Main Authors Vial, S., Prevot, V., Leroux, F., Forano, C.
Format Journal Article Conference Proceeding
LanguageEnglish
Published Amsterdam Elsevier Inc 2008
Elsevier
Subjects
Bio-inorganic materials
Chemistry
Colloidal state and disperse state
Enzyme biosensor
Exact sciences and technology
General and physical chemistry
Layered double hydroxide
Porous materials
Urease
Urease
Enzyme biosensor
Bio-inorganic materials
Layered double hydroxide
Chemistry
Lamellar compound
Enzyme
Biosensor
Immobilization
Nanocomposite
Nanotechnology
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Summary:Immobilization of urease in Zn RAl layered double hydroxides is realized in order to develop novel urea biosensors for medical diagnosis and continuous monitoring devices for the environment. Different soft chemistry preparation methods are tested and compared. Adsorption isotherms of urease on ZnAl LDH with various Zn/Al molar ratios are of L-Type and indicate that the amount of adsorbed enzyme is directly dependent on the anion exchange capacity of the host structure. Confinement of urease by delamination/restacking and coprecipitation processes leads to higher amount of embedded urease and strong modification of the structure and morphology of the materials comparatively to the Zn RAl–Cl reference phases. The nanohybrid bioinorganic Zn RAl–urease materials display a loss of crystallinity and a melted-like aggregation as the amount of intercalated urease increases. The LDH layers are always present in the hybrid materials in a more or less dispersed state, however, EXAFS study mainly evidences that the typical local ordering of the LDH layers is retained even under such direct preparative routes. Structural and textural properties are discussed in relation to the preservation of urease activity, permeability toward molecular diffusion and electrochemical performances of the derived biosensors.
ISSN:1387-1811
1873-3093
DOI:10.1016/j.micromeso.2007.02.033