Bioconversion of wheat bran into high value-added products and modelling of fermentations

Bioconversion of wheat bran into high value-added products and modelling of fermentations

•Optimal pretreatment conditions were 1 min, 1.19% acid ratio and 11.97:1 L/S ratio.•RSC, Glu, Xyl, Ara levels were 41.08, 17.66, 6.93 and 3.78 g/L at optimal conditions.•PH, HMF, 2-F, E levels were 468.1, 247.84, 7.27 mg/L and 39.28 g/g, respectively.•EtOH, LA and Iase levels were 3.85 g/L, 9.09 g/...

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Bibliographic Details
Published in:Industrial crops and products Vol. 139; p. 111565
Main Authors: Germec, Mustafa, Ozcan, Ali, Turhan, Irfan
Format: Journal Article
Language:English
Published: Elsevier B.V 01-11-2019
Subjects:
Central composite design
Ethanol
Inulinase
Lactic acid
Lignocellulose
Modeling
Central composite design
Sugarmax
A0
Lignocellulose
AIC
yt
QP
AA
R2
RSC
Pmin
Ethanol
Xmax
Iase
YP/Sugar
SSase
MAE
Ara
Pmax
RSS
EY
SUY
RSY
λ
E
h0
EtOH
I
Am
Modeling
N
P
At
S
Xmin
Inulinase
D-glca
X
Sugar
HMF
Sase
Xfinal
Xyl
2-F
RMSE
t
LA
Sugarmin
PHs
Lactic acid
xt
Glc
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Description
Summary:•Optimal pretreatment conditions were 1 min, 1.19% acid ratio and 11.97:1 L/S ratio.•RSC, Glu, Xyl, Ara levels were 41.08, 17.66, 6.93 and 3.78 g/L at optimal conditions.•PH, HMF, 2-F, E levels were 468.1, 247.84, 7.27 mg/L and 39.28 g/g, respectively.•EtOH, LA and Iase levels were 3.85 g/L, 9.09 g/L and 116.85 U/mL, respectively.•Huang model fitted very well the observed production data compared to Baranyi model. The objectives of this study were to determine the particle size of wheat bran (WB), to optimize the pretreatment conditions of WB and to produce ethanol (EtOH), lactic acid (LA), and inulinase (Iase) from acid-pretreated and non-detoxified wheat bran. Another objective was to predict the experimental production data of the fermentations using mathematical models. It was found that the optimum acid-pretreatment conditions of WB were 1 min of pretreatment time, 1.99% (v/v) dilute-acid ratio, and 11.97:1 of liquid-to-solid ratio (v/w) at a fixed temperature (121 °C). Under optimal conditions, the levels of reducing sugar, phenolics, glucose, xylose, arabinose, acetic acid, 5-hydroxymethyl furfural, 2-furaldehyde and the catalytic efficiency (E, g sugar/g inhibitor) were 41.08 g/L (0.49 g sugar/g biomass), 468.10 mg/L, 17.66 g/L, 6.93 g/L, 3.78 g/L, 0 g/L, 247.84 mg/L, 7.27 mg/L, and 39.28 g/g, respectively. Maximum EtOH and LA yields were obtained as 30.44% (3.85 g/L, 59.57% of theoretical yield) and 66.68% (9.09 g/L) when the free Scheffersomyces stipitis (ATCC 58,784) and the immobilized Lactobacillus casei were used, respectively. Nevertheless, Iase activity (I), invertase-type activity (S) and S/I ratio were 116.85 U/mL, 44.88 U/mL and 0.38 when Aspergillus niger A42 was employed, respectively. As concerning mathematical modeling, Huang model was more successful than Baranyi model in predicting the experimental production data. Overall, WB can be used as a good substrate source for production of value-added products by microbial processes.
ISSN:0926-6690
1872-633X
DOI:10.1016/j.indcrop.2019.111565