Bionanofabrication of Cupric oxide catalyst from Water hyacinth based carbohydrate and its impact on cellulose deconstructing enzymes production under solid state fermentation

Bionanofabrication of Cupric oxide catalyst from Water hyacinth based carbohydrate and its impact on cellulose deconstructing enzymes production under solid state fermentation

One of the most important properties of cellulolytic enzyme is its ability to convert cellulosic polymer into monomeric fermentable sugars which are carbohydrate by nature can efficiently convert into biofuels. However, higher production costs of these enzymes with moderate activity-based stability...

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Bibliographic Details
Published in:International journal of biological macromolecules Vol. 252; p. 126377
Main Authors: Singh, Rajeev, Singh, Pardeep, Ahmad, Irfan, Alkhathami, Ali G., Rai, Ashutosh Kumar, Mishra, P.K., Singh, Ravindra Pratap, Srivastava, Neha
Format: Journal Article
Language:English
Published: Elsevier B.V 01-12-2023
Subjects:
Cellulases
CuO NPs
Enzyme production
Solid state fermentation
Temperature stability
Water hyacinth
Water hyacinth
Cellulases
Enzyme production
Solid state fermentation
CuO NPs
Temperature stability
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Summary:One of the most important properties of cellulolytic enzyme is its ability to convert cellulosic polymer into monomeric fermentable sugars which are carbohydrate by nature can efficiently convert into biofuels. However, higher production costs of these enzymes with moderate activity-based stability are the main obstacles to making cellulase-based applications sustainably viable, and this has necessitated rigorous research for the economical availability of this process. Using water hyacinth (WH) waste leaves as the substrate for cellulase production under solid state fermentation (SSF) while treating the fermentation production medium with CuO (cupric oxide oxide) bionanocatalyst have been examined as ways to make fungal cellulase production economically feasible. Herein, a sustainable green synthesis of CuO bionanocatalyst has been performed by using waste leaves of WH. Through XRD, FT-IR, SEM, and TEM analysis, the prepared CuO bionanocatalyst's physicochemical properties have been evaluated. Furthermore, the effect of CuO bionanocatalyst on the temperature stability of raw cellulases was observed, and its half-life stability was found to be up to 9 h at 65 °C. The results presented in the current investigation may have broad scope for mass trials for various industrial applications, such as cellulosic biomass conversion.
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ISSN:0141-8130
1879-0003
DOI:10.1016/j.ijbiomac.2023.126377