TY - JOUR
T1 - Biohydrogen production from cellulosic hydrolysate produced via temperature-shift-enhanced bacterial cellulose hydrolysis
AU - Lo, Yung Chung
AU - Su, Yi Chen
AU - Chen, Chun Yen
AU - Chen, Wen Ming
AU - Lee, Kuo Shing
AU - Chang, Jo Shu
N1 - Funding Information:
The authors gratefully acknowledge financial supports from Taiwan’s National Science Council (Grant Nos. NSC-95-2221-E-006-164-MY3, NSC-96-2218-E-006-295, NSC-96-2628-E-006-004-MY3 and 97-2218-E-006-005) as well as from National Cheng Kung University (Landmark program, Project No. A029).
PY - 2009/12
Y1 - 2009/12
N2 - A "temperature-shift" strategy was developed to improve reducing sugar production from bacterial hydrolysis of cellulosic materials. In this strategy, production of cellulolytic enzymes with Cellulomonas uda E3-01 was promoted at a preferable temperature (35 °C), while more efficient enzymatic cellulose hydrolysis was achieved under an elevated culture temperature (45 °C), at which cell growth was inhibited to avoid consumption of reducing sugar. This temperature-shift strategy was shown to markedly increase the reducing sugar (especially, monosaccharide and disaccharide) concentration in the hydrolysate while hydrolyzing pure (carboxymethyl-cellulose, xylan, avicel and cellobiose) and natural (rice husk, rice straw, bagasse and Napier-grass) cellulosic materials. The cellulosic hydrolysates from CMC and xylan were successfully converted to H2 via dark fermentation with Clostridium butyricum CGS5, attaining a maximum hydrogen yield of 4.79 mmol H2/g reducing sugar.
AB - A "temperature-shift" strategy was developed to improve reducing sugar production from bacterial hydrolysis of cellulosic materials. In this strategy, production of cellulolytic enzymes with Cellulomonas uda E3-01 was promoted at a preferable temperature (35 °C), while more efficient enzymatic cellulose hydrolysis was achieved under an elevated culture temperature (45 °C), at which cell growth was inhibited to avoid consumption of reducing sugar. This temperature-shift strategy was shown to markedly increase the reducing sugar (especially, monosaccharide and disaccharide) concentration in the hydrolysate while hydrolyzing pure (carboxymethyl-cellulose, xylan, avicel and cellobiose) and natural (rice husk, rice straw, bagasse and Napier-grass) cellulosic materials. The cellulosic hydrolysates from CMC and xylan were successfully converted to H2 via dark fermentation with Clostridium butyricum CGS5, attaining a maximum hydrogen yield of 4.79 mmol H2/g reducing sugar.
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U2 - 10.1016/j.biortech.2009.06.066
DO - 10.1016/j.biortech.2009.06.066
M3 - Article
C2 - 19604692
AN - SCOPUS:68649107526
SN - 0960-8524
VL - 100
SP - 5802
EP - 5807
JO - Bioresource technology
JF - Bioresource technology
IS - 23
ER -