Production of acetone, butanol, and ethanol by fermentation of Saccharina latissima::Cultivation, enzymatic hydrolysis, inhibitor removal, and fermentation

Seaweed (or macroalgae) produced sustainably at large scale opens opportunities as source of fuels, chemicals and food. The production does not directly compete with terrestrial food production and may make use of anthropogenic sources of carbon dioxide and nitrogen. Seaweed biomass can be transform...

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Published in:Algal Research
Main Authors: Schultze-jena, A., Vroon, R.c., Macleod, A.k.a., Hreggviðsson, G.ó., Adalsteinsson, B.t., Engelen-smit, N.p.e., De Vrije, T., Budde, M.a.w., Van Der Wal, H., López-contreras, A.m., Boon, M.a.
Format: Article in Journal/Newspaper
Language:English
Published: 2022
Subjects:
Marcoalgae
Seaweeds
Acetone
Butanol
Ethanol
Fermentation
Detoxification
North East Atlantic
Online Access:https://pure.uhi.ac.uk/en/publications/f1921310-787e-47d7-9ff1-aa55e7bbd162
https://doi.org/10.1016/j.algal.2021.102618
https://pureadmin.uhi.ac.uk/ws/files/17480389/1_s2.0_S2211926421004379_main.pdf
https://linkinghub.elsevier.com/retrieve/pii/S2211926421004379
id ftuhipublicatio:oai:pure.atira.dk:publications/f1921310-787e-47d7-9ff1-aa55e7bbd162
record_format openpolar
spelling ftuhipublicatio:oai:pure.atira.dk:publications/f1921310-787e-47d7-9ff1-aa55e7bbd162 2024-09-15T18:24:45+00:00 Production of acetone, butanol, and ethanol by fermentation of Saccharina latissima::Cultivation, enzymatic hydrolysis, inhibitor removal, and fermentation Schultze-jena, A. Vroon, R.c. Macleod, A.k.a. Hreggviðsson, G.ó. Adalsteinsson, B.t. Engelen-smit, N.p.e. De Vrije, T. Budde, M.a.w. Van Der Wal, H. López-contreras, A.m. Boon, M.a. 2022-03-01 application/pdf https://pure.uhi.ac.uk/en/publications/f1921310-787e-47d7-9ff1-aa55e7bbd162 https://doi.org/10.1016/j.algal.2021.102618 https://pureadmin.uhi.ac.uk/ws/files/17480389/1_s2.0_S2211926421004379_main.pdf https://linkinghub.elsevier.com/retrieve/pii/S2211926421004379 eng eng https://pure.uhi.ac.uk/en/publications/f1921310-787e-47d7-9ff1-aa55e7bbd162 info:eu-repo/semantics/openAccess Schultze-jena , A , Vroon , R C , Macleod , A K A , Hreggviðsson , G Ó , Adalsteinsson , B T , Engelen-smit , N P E , De Vrije , T , Budde , M A W , Van Der Wal , H , López-contreras , A M & Boon , M A 2022 , ' Production of acetone, butanol, and ethanol by fermentation of Saccharina latissima: Cultivation, enzymatic hydrolysis, inhibitor removal, and fermentation ' , Algal Research , vol. 62 , 102618 . https://doi.org/10.1016/j.algal.2021.102618 Marcoalgae Seaweeds Acetone Butanol Ethanol Fermentation Detoxification article 2022 ftuhipublicatio https://doi.org/10.1016/j.algal.2021.102618 2024-08-05T23:36:06Z Seaweed (or macroalgae) produced sustainably at large scale opens opportunities as source of fuels, chemicals and food. The production does not directly compete with terrestrial food production and may make use of anthropogenic sources of carbon dioxide and nitrogen. Seaweed biomass can be transformed into a suitable substrate for fermentation using a biorefinery approach. In this study the entire process of biofuel production from seaweed is described: starting with cultivation and harvest, the seaweed is dried and cut, enzymatically hydrolysed, demineralized, detoxified, and finally fermented into acetone, butanol, and ethanol (ABE). Juvenile Saccharina latissima was directly seeded on AlgaeTex® nets and cultivated in the North East Atlantic off the west coast of Scotland for 6 months. Sun dried seaweed was hydrolysed with different enzymes, looking for optimal glucose release, solid/liquid ratio, and enzyme load. Using Cellic® CTec2 in combination with alginate lyases, approximately 80% of available glucose was released. The hydrolysis was scaled up to 100 L, using only Cellic® CTec2. Part of the hydrolysate was demineralized using ion-exclusion chromatography, removing over 90% of minerals while recovering 92% of glucose and mannitol. A fraction of the demineralized hydrolysate was additionally detoxified using a hydrophobic resin to remove hydrophobic components to a concentration below detection limit. The three hydrolysates (untreated, demineralized, and demineralized followed by detoxification) were used as substrate for ABE production by a newly developed strain of Clostridium acetobutylicum adapted to grow on S. latissima hydrolysate. Demineralization reduced the lag phase of fermentation from 72 h (untreated) to 24–48 h. Further detoxification of the hydrolysate led to immediate fermentation, resulting in a yield of 0.23 ± 0.02 gABE/gsugar similar to control fermentation in control medium (0.19 gABE/gsugar). Article in Journal/Newspaper North East Atlantic University of the Highlands and Islands: Research Database of UHI Algal Research 62 102618
institution Open Polar
collection University of the Highlands and Islands: Research Database of UHI
op_collection_id ftuhipublicatio
language English
topic Marcoalgae
Seaweeds
Acetone
Butanol
Ethanol
Fermentation
Detoxification
spellingShingle Marcoalgae
Seaweeds
Acetone
Butanol
Ethanol
Fermentation
Detoxification
Schultze-jena, A.
Vroon, R.c.
Macleod, A.k.a.
Hreggviðsson, G.ó.
Adalsteinsson, B.t.
Engelen-smit, N.p.e.
De Vrije, T.
Budde, M.a.w.
Van Der Wal, H.
López-contreras, A.m.
Boon, M.a.
Production of acetone, butanol, and ethanol by fermentation of Saccharina latissima::Cultivation, enzymatic hydrolysis, inhibitor removal, and fermentation
topic_facet Marcoalgae
Seaweeds
Acetone
Butanol
Ethanol
Fermentation
Detoxification
description Seaweed (or macroalgae) produced sustainably at large scale opens opportunities as source of fuels, chemicals and food. The production does not directly compete with terrestrial food production and may make use of anthropogenic sources of carbon dioxide and nitrogen. Seaweed biomass can be transformed into a suitable substrate for fermentation using a biorefinery approach. In this study the entire process of biofuel production from seaweed is described: starting with cultivation and harvest, the seaweed is dried and cut, enzymatically hydrolysed, demineralized, detoxified, and finally fermented into acetone, butanol, and ethanol (ABE). Juvenile Saccharina latissima was directly seeded on AlgaeTex® nets and cultivated in the North East Atlantic off the west coast of Scotland for 6 months. Sun dried seaweed was hydrolysed with different enzymes, looking for optimal glucose release, solid/liquid ratio, and enzyme load. Using Cellic® CTec2 in combination with alginate lyases, approximately 80% of available glucose was released. The hydrolysis was scaled up to 100 L, using only Cellic® CTec2. Part of the hydrolysate was demineralized using ion-exclusion chromatography, removing over 90% of minerals while recovering 92% of glucose and mannitol. A fraction of the demineralized hydrolysate was additionally detoxified using a hydrophobic resin to remove hydrophobic components to a concentration below detection limit. The three hydrolysates (untreated, demineralized, and demineralized followed by detoxification) were used as substrate for ABE production by a newly developed strain of Clostridium acetobutylicum adapted to grow on S. latissima hydrolysate. Demineralization reduced the lag phase of fermentation from 72 h (untreated) to 24–48 h. Further detoxification of the hydrolysate led to immediate fermentation, resulting in a yield of 0.23 ± 0.02 gABE/gsugar similar to control fermentation in control medium (0.19 gABE/gsugar).
format Article in Journal/Newspaper
author Schultze-jena, A.
Vroon, R.c.
Macleod, A.k.a.
Hreggviðsson, G.ó.
Adalsteinsson, B.t.
Engelen-smit, N.p.e.
De Vrije, T.
Budde, M.a.w.
Van Der Wal, H.
López-contreras, A.m.
Boon, M.a.
author_facet Schultze-jena, A.
Vroon, R.c.
Macleod, A.k.a.
Hreggviðsson, G.ó.
Adalsteinsson, B.t.
Engelen-smit, N.p.e.
De Vrije, T.
Budde, M.a.w.
Van Der Wal, H.
López-contreras, A.m.
Boon, M.a.
author_sort Schultze-jena, A.
title Production of acetone, butanol, and ethanol by fermentation of Saccharina latissima::Cultivation, enzymatic hydrolysis, inhibitor removal, and fermentation
title_short Production of acetone, butanol, and ethanol by fermentation of Saccharina latissima::Cultivation, enzymatic hydrolysis, inhibitor removal, and fermentation
title_full Production of acetone, butanol, and ethanol by fermentation of Saccharina latissima::Cultivation, enzymatic hydrolysis, inhibitor removal, and fermentation
title_fullStr Production of acetone, butanol, and ethanol by fermentation of Saccharina latissima::Cultivation, enzymatic hydrolysis, inhibitor removal, and fermentation
title_full_unstemmed Production of acetone, butanol, and ethanol by fermentation of Saccharina latissima::Cultivation, enzymatic hydrolysis, inhibitor removal, and fermentation
title_sort production of acetone, butanol, and ethanol by fermentation of saccharina latissima::cultivation, enzymatic hydrolysis, inhibitor removal, and fermentation
publishDate 2022
url https://pure.uhi.ac.uk/en/publications/f1921310-787e-47d7-9ff1-aa55e7bbd162
https://doi.org/10.1016/j.algal.2021.102618
https://pureadmin.uhi.ac.uk/ws/files/17480389/1_s2.0_S2211926421004379_main.pdf
https://linkinghub.elsevier.com/retrieve/pii/S2211926421004379
genre North East Atlantic
genre_facet North East Atlantic
op_source Schultze-jena , A , Vroon , R C , Macleod , A K A , Hreggviðsson , G Ó , Adalsteinsson , B T , Engelen-smit , N P E , De Vrije , T , Budde , M A W , Van Der Wal , H , López-contreras , A M & Boon , M A 2022 , ' Production of acetone, butanol, and ethanol by fermentation of Saccharina latissima: Cultivation, enzymatic hydrolysis, inhibitor removal, and fermentation ' , Algal Research , vol. 62 , 102618 . https://doi.org/10.1016/j.algal.2021.102618
op_relation https://pure.uhi.ac.uk/en/publications/f1921310-787e-47d7-9ff1-aa55e7bbd162
op_rights info:eu-repo/semantics/openAccess
op_doi https://doi.org/10.1016/j.algal.2021.102618
container_title Algal Research
container_volume 62
container_start_page 102618
_version_ 1810465181480779776

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