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Increased Enzyme Production via Pretreatments

Summary: Researchers at Purdue University have developed technology that utilizes liquefaction of pretreated and sterilized sugarcane bagasse for enhancing endoglucanase production through SmF by Aspergillus niger (A. niger). After initial SSF of steam pretreated bagasse solids by A. niger, fed-batch addition of the substrate to cellulase in buffer and reaction, resulted in a liquid slurry with a viscosity of 0.30 ± 0.07 Pa•s at 30% (w/v) solids. The addition of A. niger for submerged fermentation of sterile liquefied bagasse at 23% (w/v) solids resulted in approximately 15 times higher productivity than SSF of non-liquefied bagasse. These results demonstrate the utility of liquefied bagasse as a culture medium for enzyme production in submerged fermentations.

Technology Benefits: Reduced power input required for mixing the slurry Liquefied biomass gives a 15 times higher enzyme yield compared to solid-state fermentation Enhancement of the enzyme yield

Technology Application: Chemical analysis companiesChemical analysis laboratories

Detailed Technology Description: Michael LadischPurdue Agricultural and Biological EngineeringLORRE Laboratory of Renewable Resources Engineering

Countries: United States

Application No.: N/A

*Abstract

*Background: The industrial competitiveness of second-generation cellulose ethanol depends on achieving efficient production and use of cellulase enzymes. Cellulase production by filamentous fungi may be achieved through either solid-state fermentation (SSF) or submerged fermentation (SmF). Despite many advantages of SSF over SmF, enzyme production in large-scale SSF bioreactors is hindered by low-solids loadings or if high solids are used, by solids handling and mass and heat transfer gradients during the cultivation process. Submerged cultivations with high-solids loadings remain challenging since mass transfer and gas holdup limitations are compounded by viscosity increases that occur during the first hours of cultivation due to fungal growth.

*IP Issue Date: None

*IP Type: Provisional

*Stage of Development: Proof of concept

*Web Links: Purdue Office of Technology CommercializationPurdue Innovation and EntrepreneurshipMichael LadischPurdue Agricultural and Biological EngineeringLORRE Laboratory of Renewable Resources Engineering

Country/Region: USA

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