Ensiling of sugar kelp biomass for biorefining

Søren Ugilt Larsen; Nikolaj  Ma; Xiaoru Hou; Annette Bruhn; Teis Boderskov; Adrian McLeod; Urd Grandorf Bak; Anne-Belinda Bjerre

doi:10.1016/j.biombioe.2021.106134

Ensiling of sugar kelp biomass for biorefining

Søren Ugilt Larsen^*, Nikolaj Ma, Xiaoru Hou, Annette Bruhn, Teis Boderskov, Adrian McLeod, Urd Grandorf Bak, Anne-Belinda Bjerre

^*Corresponding author af dette arbejde

Center for Cirkulær Bioøkonomi, Foulum

Publikation: Bidrag til tidsskrift/Konferencebidrag i tidsskrift /Bidrag til avis › Tidsskriftartikel › Forskning › peer review

7 Citationer (Scopus)

Abstract

Ensiling was investigated as a long-term storage method for preserving brown seaweed biomass (sugar kelp, Saccharina latissima (Phaeophyceae)) for subsequent use e.g. in a year-round biorefinery context where value-added constituents should be recovered for further formulation. Sugar kelp ensiling trials were carried out in lab-scale and pilot-scale with up to one-year duration, by either biological ensiling by means of lactic acid bacteria (LAB) fermentation or by chemical ensiling by addition of lactic acid to reduce pH. The results clearly demonstrated that the ensilability of sugar kelp was positively correlated with the initial glucose content which was partly consumed by LAB for obtaining and maintaining low pH. The ensiling process could be optimized by initial addition of molasses and further by addition of commercial LAB inoculum. The dose of molasses was important for pH development during biological ensiling. Similarly, initial addition of lactic acid was important for obtaining an effective chemical ensiling. Biological ensiling reduced the content of native glucose from sugar kelp and increased the content of fermentation products, primarily lactic acid. Addition of either molasses + LAB inoculum or lactic acid reduced the degradation of total amino acids during ensiling. Freezing prior to ensiling hampered the ensiling process but could be compensated for by addition of LAB. In conclusion, ensiling can be used for long-term storage of seaweed biomass, however, the ensiling process alters the biomass composition and, hence, the quality for subsequent use in biorefinery processes. The fate of higher-value components during ensiling needs further investigation.

Originalsprog	Engelsk
Artikelnummer	106134
Tidsskrift	Biomass & Bioenergy
Vol/bind	151
ISSN	0961-9534
DOI	https://doi.org/10.1016/j.biombioe.2021.106134
Status	Udgivet - aug. 2021

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10.1016/j.biombioe.2021.106134

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1 Afsluttet
1 Igangværende

CBIO: Aarhus Universitets Center for Cirkulær Bioøkonomi
Jørgensen, U. (PI), Thomsen, M. (Deltager), Bruhn, A. (Deltager), Glasius, M. (Deltager), Jensen, S. K. (Deltager), Dalsgaard, T. K. (Deltager), Andersen, M. S. (Deltager) & Ambye-Jensen, M. (Deltager)
01/05/2017 → …
Projekter: Projekt › Forskning
MacroFuels
Bruhn, A. (Deltager) & Rasmussen, M. B. (Deltager)
01/01/2016 → 31/12/2019
Projekter: Projekt › Forskning

Citationsformater

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title = "Ensiling of sugar kelp biomass for biorefining",

abstract = "Ensiling was investigated as a long-term storage method for preserving brown seaweed biomass (sugar kelp, Saccharina latissima (Phaeophyceae)) for subsequent use e.g. in a year-round biorefinery context where value-added constituents should be recovered for further formulation. Sugar kelp ensiling trials were carried out in lab-scale and pilot-scale with up to one-year duration, by either biological ensiling by means of lactic acid bacteria (LAB) fermentation or by chemical ensiling by addition of lactic acid to reduce pH. The results clearly demonstrated that the ensilability of sugar kelp was positively correlated with the initial glucose content which was partly consumed by LAB for obtaining and maintaining low pH. The ensiling process could be optimized by initial addition of molasses and further by addition of commercial LAB inoculum. The dose of molasses was important for pH development during biological ensiling. Similarly, initial addition of lactic acid was important for obtaining an effective chemical ensiling. Biological ensiling reduced the content of native glucose from sugar kelp and increased the content of fermentation products, primarily lactic acid. Addition of either molasses + LAB inoculum or lactic acid reduced the degradation of total amino acids during ensiling. Freezing prior to ensiling hampered the ensiling process but could be compensated for by addition of LAB. In conclusion, ensiling can be used for long-term storage of seaweed biomass, however, the ensiling process alters the biomass composition and, hence, the quality for subsequent use in biorefinery processes. The fate of higher-value components during ensiling needs further investigation.",

keywords = "Biorefinery, Chemical composition, Fermentation, Macroalgae, Quality, Storage",

author = "Larsen, {S{\o}ren Ugilt} and Nikolaj Ma and Xiaoru Hou and Annette Bruhn and Teis Boderskov and Adrian McLeod and Bak, {Urd Grandorf} and Anne-Belinda Bjerre",

year = "2021",

month = aug,

doi = "10.1016/j.biombioe.2021.106134",

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T1 - Ensiling of sugar kelp biomass for biorefining

AU - Larsen, Søren Ugilt

AU - Ma, Nikolaj

AU - Hou, Xiaoru

AU - Bruhn, Annette

AU - Boderskov, Teis

AU - McLeod, Adrian

AU - Bak, Urd Grandorf

AU - Bjerre, Anne-Belinda

PY - 2021/8

Y1 - 2021/8

N2 - Ensiling was investigated as a long-term storage method for preserving brown seaweed biomass (sugar kelp, Saccharina latissima (Phaeophyceae)) for subsequent use e.g. in a year-round biorefinery context where value-added constituents should be recovered for further formulation. Sugar kelp ensiling trials were carried out in lab-scale and pilot-scale with up to one-year duration, by either biological ensiling by means of lactic acid bacteria (LAB) fermentation or by chemical ensiling by addition of lactic acid to reduce pH. The results clearly demonstrated that the ensilability of sugar kelp was positively correlated with the initial glucose content which was partly consumed by LAB for obtaining and maintaining low pH. The ensiling process could be optimized by initial addition of molasses and further by addition of commercial LAB inoculum. The dose of molasses was important for pH development during biological ensiling. Similarly, initial addition of lactic acid was important for obtaining an effective chemical ensiling. Biological ensiling reduced the content of native glucose from sugar kelp and increased the content of fermentation products, primarily lactic acid. Addition of either molasses + LAB inoculum or lactic acid reduced the degradation of total amino acids during ensiling. Freezing prior to ensiling hampered the ensiling process but could be compensated for by addition of LAB. In conclusion, ensiling can be used for long-term storage of seaweed biomass, however, the ensiling process alters the biomass composition and, hence, the quality for subsequent use in biorefinery processes. The fate of higher-value components during ensiling needs further investigation.

AB - Ensiling was investigated as a long-term storage method for preserving brown seaweed biomass (sugar kelp, Saccharina latissima (Phaeophyceae)) for subsequent use e.g. in a year-round biorefinery context where value-added constituents should be recovered for further formulation. Sugar kelp ensiling trials were carried out in lab-scale and pilot-scale with up to one-year duration, by either biological ensiling by means of lactic acid bacteria (LAB) fermentation or by chemical ensiling by addition of lactic acid to reduce pH. The results clearly demonstrated that the ensilability of sugar kelp was positively correlated with the initial glucose content which was partly consumed by LAB for obtaining and maintaining low pH. The ensiling process could be optimized by initial addition of molasses and further by addition of commercial LAB inoculum. The dose of molasses was important for pH development during biological ensiling. Similarly, initial addition of lactic acid was important for obtaining an effective chemical ensiling. Biological ensiling reduced the content of native glucose from sugar kelp and increased the content of fermentation products, primarily lactic acid. Addition of either molasses + LAB inoculum or lactic acid reduced the degradation of total amino acids during ensiling. Freezing prior to ensiling hampered the ensiling process but could be compensated for by addition of LAB. In conclusion, ensiling can be used for long-term storage of seaweed biomass, however, the ensiling process alters the biomass composition and, hence, the quality for subsequent use in biorefinery processes. The fate of higher-value components during ensiling needs further investigation.

KW - Biorefinery

KW - Chemical composition

KW - Fermentation

KW - Macroalgae

KW - Quality

KW - Storage

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JO - Biomass & Bioenergy

JF - Biomass & Bioenergy

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ER -

Ensiling of sugar kelp biomass for biorefining

Abstract

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