Influence of Bacterial Cellulose Gel Film Modification on Its Mechanical Properties and Ability to Covalently Bind Enzymes

Influence of Bacterial Cellulose Gel Film Modification on Its Mechanical Properties and Ability to Covalently Bind Enzymes

The rules for modifying the gel film of bacterial cellulose without disturbing its film structure are optimized. Using FTIR spectroscopy and titration, it is shown that oxidation with sodium periodate makes it possible to obtain dialdehyde derivatives of gel films with different amounts of aldehyde...

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Veröffentlicht in:Polymer science. Series B 2021, Vol.63 (3), p.232-238
Hauptverfasser: Kadimaliev, D. A., Devyataeva, A. A., Grunyushkin, I. P., Malafeev, A. N., Revin, V. V.
Format: Artikel
Sprache:eng
Schlagworte:
Aldehydes
Cellulose
Chemistry
Chemistry and Materials Science
Enzymes
Galactosidase
Immobilization
Infrared analysis
Infrared spectroscopy
Mechanical properties
Modification of Polymers
Oxidation
Pepsin
Polymer Sciences
Spectrum analysis
Titration
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Zusammenfassung:The rules for modifying the gel film of bacterial cellulose without disturbing its film structure are optimized. Using FTIR spectroscopy and titration, it is shown that oxidation with sodium periodate makes it possible to obtain dialdehyde derivatives of gel films with different amounts of aldehyde groups. The conditions for immobilizing pepsin and β-galactosidase enzymes on modified gel films are selected. An analysis of IR spectra shows that the enzymes are retained on the gel film owing to formation of azomethine bonds between the amino groups of the protein and the aldehyde groups of the film. The efficiency of immobilization depends on the type of enzyme and the conditions of the grafting reaction; under the same conditions, the gel film binds more β-galactosidase than pepsin.
ISSN:1560-0904
1555-6123
DOI:10.1134/S1560090421030088