Direct utilization of kitchen waste for bioethanol production by separate hydrolysis and fermentation (SHF) using locally isolated yeast

Kitchen wastes containing high amounts of carbohydrates have potential as low-cost substrates for fermentable sugar production. In this study, enzymatic saccharification of kitchen waste was carried out. Response surface methodology (RSM) was applied to optimize the enzymatic saccharification condit...

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Bibliographic Details
Published in:International journal of green energy 2016-01, Vol.13 (3), p.248-259
Main Authors: Hafid, Halimatun Saadiah, Abdul Rahman, Nor'Aini, Md Shah, Umi Kalsom, Samsu Baharudin, Azhari, Zakaria, Rabitah
Format: Article
Language:English
Subjects:
Bioethanol
Candida
enzymatic hydrolysis
fermentable sugars
Glucoamylase
Hydrolysis
kitchen waste
Kitchens
Mathematical models
response surface methodology (RSM)
Saccharification
Saccharomyces cerevisiae
Sugars
Wastes
Yeast
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Summary:Kitchen wastes containing high amounts of carbohydrates have potential as low-cost substrates for fermentable sugar production. In this study, enzymatic saccharification of kitchen waste was carried out. Response surface methodology (RSM) was applied to optimize the enzymatic saccharification conditions of kitchen waste. This paper presents analysis of RSM in a predictive model of the combined effects of independent variables (pH, temperature, glucoamylase activity, kitchen waste loading, and hydrolysis time) as the most significant parameters for fermentable sugar production and degree of saccharification. A 100 mL of kitchen waste was hydrolyzed in 250 mL of shake flasks. Quadratic RSM predicted maximum fermentable sugar production of 62.79 g/L and degree of saccharification (59.90%) at the following optimal conditions: pH 5, temperature 60°C, glucoamylase activity of 85 U/mL, and utilized 60 g/L of kitchen waste as a substrate at 10 h hydrolysis time. The verification experiments successfully produced 62.71 ± 0.7 g/L of fermentable sugar with 54.93 ± 0.4% degree of saccharification within 10 h of incubation, indicating that the developed model was successfully used to predict fermentable sugar production at more than 90% accuracy. The sugars produced after hydrolysis of kitchen waste were mainly attributed to monosaccharide: glucose (80%) and fructose (20%). The fermentable sugars obtained were subsequently used as carbon source for bioethanol production by locally isolated yeasts: Saccharomyces cerevisiae, Candida parasilosis , and Lanchancea fermentati . The yeasts were successfully consumed as sugars hydrolysate, and produced the highest ethanol yield ranging from 0.45 to 0.5 g/g and productivity between 0.44 g L –¹ h –¹ and 0.47 g L –¹ h –¹ after 24-h incubation, which was equivalent to 82.06–98.19% of conversion based on theoretical yield.
ISSN:1543-5083
1543-5075
1543-5083
DOI:10.1080/15435075.2014.940958