Ethanol Production from Olive Stones through Liquid Hot Water Pre-Treatment, Enzymatic Hydrolysis and Fermentation. Influence of Enzyme Loading, and Pre-Treatment Temperature and Time

Ethanol Production from Olive Stones through Liquid Hot Water Pre-Treatment, Enzymatic Hydrolysis and Fermentation. Influence of Enzyme Loading, and Pre-Treatment Temperature and Time

Olive table industry, olive mills and olive pomace oil extraction industries annually generate huge amounts of olive stones. One of their potential applications is the production of bioethanol by fractionation of their lignocellulose constituents and subsequent fermentation of the released sugars us...

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Main Authors: Manuel Cuevas, Juan F. García Martín, Vicente Bravo, Sebastián Sánchez
Format: Article
Language:English
Published: MDPI AG 2021-02-01
Series:Fermentation
Subjects:
autohydrolysis
bioethanol
Chrastil’s model
enzymatic hydrolysis
olive stones
<i>Pachysolen tannophilus</i>
Online Access:https://www.mdpi.com/2311-5637/7/1/25
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spelling doaj-2344996d4ce0448cbac1e660955742662021-02-18T00:01:55ZengMDPI AGFermentation2311-56372021-02-017252510.3390/fermentation7010025Ethanol Production from Olive Stones through Liquid Hot Water Pre-Treatment, Enzymatic Hydrolysis and Fermentation. Influence of Enzyme Loading, and Pre-Treatment Temperature and TimeManuel Cuevas0Juan F. García Martín1Vicente Bravo2Sebastián Sánchez3Department of Chemical, Environmental and Materials Engineering, Campus ‘Las Lagunillas’, University of Jaén, 23071 Jaén, SpainCenter for Advanced Studies in Olive Grove and Olive Oils, Science and Technology Park GEOLIT, 23620 Mengíbar, SpainDepartment of Chemical Engineering, Campus ‘Fuente Nueva’, University of Granada, 18071 Granada, SpainDepartment of Chemical, Environmental and Materials Engineering, Campus ‘Las Lagunillas’, University of Jaén, 23071 Jaén, SpainOlive table industry, olive mills and olive pomace oil extraction industries annually generate huge amounts of olive stones. One of their potential applications is the production of bioethanol by fractionation of their lignocellulose constituents and subsequent fermentation of the released sugars using yeasts. In this work, we studied the influence of temperature (175–225 °C) and residence time (0–5 min) in the liquid hot-water pre-treatment of olive stones as well as the initial enzyme loading (different mixtures of cellulases, hemicellulases and β–glucosidases) in the later enzymatic hydrolysis on the release of fermentable sugars. The Chrastil’s model was applied to the <span style="font-variant: small-caps;">d</span>-glucose data to relate the severity of pre-treatment to enzyme diffusion through the pre-treated cellulose. Finally, the hydrolysate obtained under the most suitable conditions (225 °C and 0 min for pre-treatment; 24 CE initial enzyme concentration) was fermented into ethanol using the yeast <i>Pachysolen tannophilus</i> ATCC 32691. Considering the overall process, 6.4 dm<sup>3</sup> ethanol per 100 kg olive stones were produced.https://www.mdpi.com/2311-5637/7/1/25autohydrolysisbioethanolChrastil’s modelenzymatic hydrolysisolive stones<i>Pachysolen tannophilus</i>
collection DOAJ
language English
format Article
sources DOAJ
author Manuel Cuevas
Juan F. García Martín
Vicente Bravo
Sebastián Sánchez
spellingShingle Manuel Cuevas
Juan F. García Martín
Vicente Bravo
Sebastián Sánchez
Ethanol Production from Olive Stones through Liquid Hot Water Pre-Treatment, Enzymatic Hydrolysis and Fermentation. Influence of Enzyme Loading, and Pre-Treatment Temperature and Time
Fermentation
autohydrolysis
bioethanol
Chrastil’s model
enzymatic hydrolysis
olive stones
<i>Pachysolen tannophilus</i>
author_facet Manuel Cuevas
Juan F. García Martín
Vicente Bravo
Sebastián Sánchez
author_sort Manuel Cuevas
title Ethanol Production from Olive Stones through Liquid Hot Water Pre-Treatment, Enzymatic Hydrolysis and Fermentation. Influence of Enzyme Loading, and Pre-Treatment Temperature and Time
title_short Ethanol Production from Olive Stones through Liquid Hot Water Pre-Treatment, Enzymatic Hydrolysis and Fermentation. Influence of Enzyme Loading, and Pre-Treatment Temperature and Time
title_full Ethanol Production from Olive Stones through Liquid Hot Water Pre-Treatment, Enzymatic Hydrolysis and Fermentation. Influence of Enzyme Loading, and Pre-Treatment Temperature and Time
title_fullStr Ethanol Production from Olive Stones through Liquid Hot Water Pre-Treatment, Enzymatic Hydrolysis and Fermentation. Influence of Enzyme Loading, and Pre-Treatment Temperature and Time
title_full_unstemmed Ethanol Production from Olive Stones through Liquid Hot Water Pre-Treatment, Enzymatic Hydrolysis and Fermentation. Influence of Enzyme Loading, and Pre-Treatment Temperature and Time
title_sort ethanol production from olive stones through liquid hot water pre-treatment, enzymatic hydrolysis and fermentation. influence of enzyme loading, and pre-treatment temperature and time
publisher MDPI AG
series Fermentation
issn 2311-5637
publishDate 2021-02-01
description Olive table industry, olive mills and olive pomace oil extraction industries annually generate huge amounts of olive stones. One of their potential applications is the production of bioethanol by fractionation of their lignocellulose constituents and subsequent fermentation of the released sugars using yeasts. In this work, we studied the influence of temperature (175–225 °C) and residence time (0–5 min) in the liquid hot-water pre-treatment of olive stones as well as the initial enzyme loading (different mixtures of cellulases, hemicellulases and β–glucosidases) in the later enzymatic hydrolysis on the release of fermentable sugars. The Chrastil’s model was applied to the <span style="font-variant: small-caps;">d</span>-glucose data to relate the severity of pre-treatment to enzyme diffusion through the pre-treated cellulose. Finally, the hydrolysate obtained under the most suitable conditions (225 °C and 0 min for pre-treatment; 24 CE initial enzyme concentration) was fermented into ethanol using the yeast <i>Pachysolen tannophilus</i> ATCC 32691. Considering the overall process, 6.4 dm<sup>3</sup> ethanol per 100 kg olive stones were produced.
topic autohydrolysis
bioethanol
Chrastil’s model
enzymatic hydrolysis
olive stones
<i>Pachysolen tannophilus</i>
url https://www.mdpi.com/2311-5637/7/1/25
work_keys_str_mv AT manuelcuevas ethanolproductionfromolivestonesthroughliquidhotwaterpretreatmentenzymatichydrolysisandfermentationinfluenceofenzymeloadingandpretreatmenttemperatureandtime
AT juanfgarciamartin ethanolproductionfromolivestonesthroughliquidhotwaterpretreatmentenzymatichydrolysisandfermentationinfluenceofenzymeloadingandpretreatmenttemperatureandtime
AT vicentebravo ethanolproductionfromolivestonesthroughliquidhotwaterpretreatmentenzymatichydrolysisandfermentationinfluenceofenzymeloadingandpretreatmenttemperatureandtime
AT sebastiansanchez ethanolproductionfromolivestonesthroughliquidhotwaterpretreatmentenzymatichydrolysisandfermentationinfluenceofenzymeloadingandpretreatmenttemperatureandtime
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