Journal
CHEMENGINEERING
Volume 7, Issue 2, Pages -Publisher
MDPI
DOI: 10.3390/chemengineering7020035
Keywords
alkali; autohydrolysis; delignification; enzymatic hydrolysis; organosolv
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Corn cob is a valuable agricultural residue that can be selectively fractionated into hemicellulose, cellulose, and lignin for the production of value-added products. This study developed and evaluated integrated fractionation approaches, including organosolv process and alkaline delignification. The results showed high delignification yields and enzymatic digestibility of cellulose for both processes. Additionally, a combined strategy of hydrothermal processing and delignification further enhanced the delignification yields and enzymatic saccharification yields. These fractionation strategies hold great promise for the integrated upgrading of corn cob in a biorefinery framework.
Corn cob is an abundant agricultural residue worldwide, with high potential and interesting composition, and its valorization still needs to be studied. Selectively fractionating its structural components (hemicellulose, cellulose, and lignin), value-added products can be produced, eliminating waste. In this work, integrated fractionation approaches were developed and evaluated. First, an organosolv process was optimized (ethanol:water, 50:50, w/w). Then, as a comparative method, alkaline delignification (using NaOH, 1-2%) was also studied. The organosolv process allowed a significant delignification of the material (79% delignification yield) and, at the same time, a liquid phase containing a relevant concentration (14.6 g/L) of xylooligosaccharides (XOS). The resulting solid fraction, rich in cellulose, showed an enzymatic digestibility of 90%. The alkaline process increased the delignification yield to 94%, producing a solid fraction with a cellulose enzymatic digestibility of 83%. The two later techniques were also used in a combined strategy of hydrothermal processing (autohydrolysis) followed by delignification. The first allowed the selective hydrolysis of hemicellulose to produce XOS-rich hydrolysates (26.8 g/L, 67.3 g/100 g initial xylan). The further delignification processes, alkaline or organosolv, led to global delignification yields of 76% and 93%, respectively. The solid residue, enriched in glucan (above 75% for both combined processes), also presented high enzymatic saccharification yields, 89% and 90%, respectively. The fractionation strategies proposed, and the results obtained are very promising, enabling the integrated upgrading of this material into a biorefinery framework.
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