Efficient enzymatic saccharification of agricultural wastes for the production of bioethanol, D-allulose and lactic acid

Efficient enzymatic saccharification of agricultural wastes for the production of bioethanol, D-allulose and lactic acid

The demand for renewable resources to replace fossil fuels has increased. Fruit and agricultural wastes can be fermented to yield biofuels and biochemicals. However, the high cost of the feedstock and limitations of the catalytic process hinder the application of such wastes. Therefore, we aimed to...

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Veröffentlicht in:Process biochemistry (1991) 2024-09, Vol.144, p.54-63
Hauptverfasser: Chang, Jihye, Song, Younho, Lee, Dae-Seok, Jegal, Eun Gyu, Nguyen, Dien Thanh, Bae, Hyeun-Jong
Format: Artikel
Sprache:eng
Schlagworte:
Agricultural residue
bioethanol
biomass
biosynthesis
catalytic activity
cost effectiveness
D-allulose
ethanol
feedstocks
fructose
Fruit waste
fruits
hydrolysates
Lactic acid
limonene
psicose
saccharification
Value-added product
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container_end_page 63
container_issue
container_start_page 54
container_title Process biochemistry (1991)
container_volume 144
creator Chang, Jihye
Song, Younho
Lee, Dae-Seok
Jegal, Eun Gyu
Nguyen, Dien Thanh
Bae, Hyeun-Jong
description The demand for renewable resources to replace fossil fuels has increased. Fruit and agricultural wastes can be fermented to yield biofuels and biochemicals. However, the high cost of the feedstock and limitations of the catalytic process hinder the application of such wastes. Therefore, we aimed to develop an efficient enzymatic saccharification process, without pretreatment, for fruit and agricultural wastes. The conversion rate of the mixed agricultural wastes (MAW) to fermentable sugars was approximately 91 % after 24 h. The ethanol yield increased by 4.5 % after limonene removal. The D-allulose yield in the hydrolysate was 4.6 mg/mL at 4 °C and 3.3 mg/mL at 50 °C, whereas the fructose yield in the sugar medium was 13.2 mg/mL at 4°C, demonstrating a high conversion yield of 73.2 %. Lactic acid was produced at a conversion rate of approximately 67.4 %. Therefore, this study presents a novel approach of the biosynthesis of functional sugars and chemicals from waste biomass, introducing a cost-effective enzymatic saccharification process that bypasses pretreatment, thereby enabling the production of biofuels, biochemicals, and functional sugars and opening up a promising economic opportunity in the field. [Display omitted] •Fruit and agricultural waste can be fermented to yield biofuels and biochemicals.•Fruit and vegetable wastes do not require pretreatment prior to saccharification.•Bioethanol yield was approximately 84.9 % after removing limonene.•The yield of D-allulose in the hydrolyzate was 4.6 mg/mL at 4°C and 3.3 mg at 50°C.•Lactic acid was produced from hydrolysate with high conversion rate.
doi_str_mv 10.1016/j.procbio.2024.05.009
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Fruit and agricultural wastes can be fermented to yield biofuels and biochemicals. However, the high cost of the feedstock and limitations of the catalytic process hinder the application of such wastes. Therefore, we aimed to develop an efficient enzymatic saccharification process, without pretreatment, for fruit and agricultural wastes. The conversion rate of the mixed agricultural wastes (MAW) to fermentable sugars was approximately 91 % after 24 h. The ethanol yield increased by 4.5 % after limonene removal. The D-allulose yield in the hydrolysate was 4.6 mg/mL at 4 °C and 3.3 mg/mL at 50 °C, whereas the fructose yield in the sugar medium was 13.2 mg/mL at 4°C, demonstrating a high conversion yield of 73.2 %. Lactic acid was produced at a conversion rate of approximately 67.4 %. 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Fruit and agricultural wastes can be fermented to yield biofuels and biochemicals. However, the high cost of the feedstock and limitations of the catalytic process hinder the application of such wastes. Therefore, we aimed to develop an efficient enzymatic saccharification process, without pretreatment, for fruit and agricultural wastes. The conversion rate of the mixed agricultural wastes (MAW) to fermentable sugars was approximately 91 % after 24 h. The ethanol yield increased by 4.5 % after limonene removal. The D-allulose yield in the hydrolysate was 4.6 mg/mL at 4 °C and 3.3 mg/mL at 50 °C, whereas the fructose yield in the sugar medium was 13.2 mg/mL at 4°C, demonstrating a high conversion yield of 73.2 %. Lactic acid was produced at a conversion rate of approximately 67.4 %. Therefore, this study presents a novel approach of the biosynthesis of functional sugars and chemicals from waste biomass, introducing a cost-effective enzymatic saccharification process that bypasses pretreatment, thereby enabling the production of biofuels, biochemicals, and functional sugars and opening up a promising economic opportunity in the field. [Display omitted] •Fruit and agricultural waste can be fermented to yield biofuels and biochemicals.•Fruit and vegetable wastes do not require pretreatment prior to saccharification.•Bioethanol yield was approximately 84.9 % after removing limonene.•The yield of D-allulose in the hydrolyzate was 4.6 mg/mL at 4°C and 3.3 mg at 50°C.•Lactic acid was produced from hydrolysate with high conversion rate.</abstract><pub>Elsevier Ltd</pub><doi>10.1016/j.procbio.2024.05.009</doi><tpages>10</tpages></addata></record>
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subjects Agricultural residue
bioethanol
biomass
biosynthesis
catalytic activity
cost effectiveness
D-allulose
ethanol
feedstocks
fructose
Fruit waste
fruits
hydrolysates
Lactic acid
limonene
psicose
saccharification
Value-added product
title Efficient enzymatic saccharification of agricultural wastes for the production of bioethanol, D-allulose and lactic acid
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