Purification of ferulic acid from corn fibre alkaline extracts for bio-vanillin production using an adsorption process

[Display omitted] •Macronet®MN102 polystyrene-divinylbenzene resin was selected for ferulic acid purification.•Breakthrough time at 115 min and 85mgferulic.acid/(gdry.resin) adsorption capacity.•The bio-vanillin production had a yield of 0.52 gvanillin/gferulic acid. Ferulic acid is the most widely...

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Published in:Separation and purification technology 2022-10, Vol.298, p.121570, Article 121570
Main Authors: Valério, Rita, Torres, Cristiana A.V., Brazinha, Carla, da Silva, Marco Gomes, Coelhoso, Isabel M., Crespo, João G.
Format: Article
Language:English
Subjects:
Adsorption
Bio-vanillin precursor
Extract purification
Ferulic acid extract
Macroporous polymeric resins
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Summary:[Display omitted] •Macronet®MN102 polystyrene-divinylbenzene resin was selected for ferulic acid purification.•Breakthrough time at 115 min and 85mgferulic.acid/(gdry.resin) adsorption capacity.•The bio-vanillin production had a yield of 0.52 gvanillin/gferulic acid. Ferulic acid is the most widely studied precursor for bio-vanillin production. This work assesses the use of an alkaline extract from corn fibre for bio-vanillin production. The results show that after extraction an additional step is needed to purify ferulic acid removing toxic/inhibitor compounds. An adsorption process was selected to purify the ferulic acid. The performances of four different macroporous resins prepared from different matrix materials were evaluated. Macronet® MN102 (not yet reported for ferulic acid purification) offered the highest ferulic acid adsorption capacity. A column packed with Macronet® MN102 was used to perform dynamic adsorption and desorption experiments, which showed a maximum ferulic acid adsorption capacity of 176 mgferulic acid.g−1dry resin at pH 4.5 at a flow rate of 3.7 BV (bed volumes).h−1. The breakthrough point was at 115 min, corresponding to an adsorption capacity of 85 mgferulic acid.g−1dry resin. In the desorption step, 90.9% of ferulic acid was recovered using absolute ethanol ≥ 99.8%) as eluent, at the same flow rate of 3.7 BV (bed volumes).h−1. This procedure confirmed the removal of compounds with a microbial inhibitory effect, such as organic acids, metals and some aldehydes. The purified ferulic acid extract was then used to produce bio-vanillin. The bio-vanillin production by Amycolatopsis sp. ATCC 39116, using a single pulse of an extract with 10 g.L-1 of ferulic acid extract, led to a maximum vanillin concentration of 5 g.L-1 and a vanillin yield of 0.52 gvanillin.gferulic acid-1, values comparable to those obtained with a commercial solution containing 10 g.L-1 of ferulic acid.
ISSN:1383-5866
1873-3794
DOI:10.1016/j.seppur.2022.121570