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Enzymatic Process for Corn Dry-Grind High-Solids Fermentation

July 2011 Volume 88 Number 4
Pages 429 — 433
Prabhjot Kaur,1 Kent D. Rausch,1 M. E. Tumbleson,1 and Vijay Singh1,2

Agricultural and Biological Engineering, University of Illinois at Urbana-Champaign, 1304 West Pennsylvania Avenue, Urbana, IL 61801. Mention of trade names or commercial products is solely for the purpose of providing specific information and does not imply recommendation or endorsement by the University of Illinois at Urbana-Champaign. Corresponding author. Phone: 217-333-9510. Fax: 217-244-0323. E-mail: vsingh@illinois.edu


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Accepted June 29, 2011.
ABSTRACT

A modified dry-grind process that combined the use of conventional amylases (glucoamylase [GA]), phytase, and granular starch hydrolyzing enzymes (GSHE) to achieve low liquefaction viscosities and low glucose concentrations during simultaneous saccharification and fermentation (SSF) with a high slurry solids content (>33% w/w) was developed. Doses of GSHE and GA were optimized for the modified process. At 35% solids content, the modified process had 80% lower slurry viscosity, 24% lower peak glucose concentration, 7.5% higher final ethanol concentration, and 51% higher fermentation rate compared with the conventional dry-grind process. At 40% solids content, the modified process had lower viscosities, lower peak and residual glucose concentrations, and higher ethanol concentrations than the conventional process; however, the results were in contrast to those for 35% solids content. At 40% solids content, SSF did not run to completion for conventional or modified processes, and more than 2.5% w/v of residual glucose was left in the fermentation broth. Final ethanol concentration achieved with the modified process at 40% solids content was 19.5% v/v, similar to the ethanol concentration achieved with the modified process at 35% solids content. At 35% slurry solids content, a GSHE level of 1.25 μL/g db of corn and a GA level of 0.25 μL/g db of corn were selected as optimum enzyme doses for the modified process.



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