Recovery of Phenolic Acid and Enzyme Production from Corn Silage Biologically Treated by Trametes versicolor

Bucić-Kojić, Ana; Šelo, Gordana; Zelić, Bruno; Planinić, M.; Tišma, Marina

doi:10.1007/s12010-016-2261-y

Cited by 26 publications

(24 citation statements)

References 46 publications

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“…BSG was a better substrate than corn silage for laccase production, since a higher activity of laccase was achieved. When corn silage was used, laccase activities of 180 U/L (in jars without addition of inducers) or 260 U/L (in a tray bioreactor, without addition of inducers) were measured (20,21). These results suggest that BSG from malt was supplemented with 60% barley, could be a promising substrate for laccase production during solid-state fermentation with T. versicolor.…”

Section: Resultsmentioning

confidence: 95%

“…In order to be used in biofuel production, different pretreatment methods need to be applied to break down the linkage between polysaccharides and lignin so as to make cellulose and hemicellulose more accessible to hydrolysis. Biological pretreatments, such as implementation of white‐rot fungi, can offer significant benefits over chemical and physical methods . During these pretreatments, various enzymes, some of them industrially important, such as laccase, are formed.…”

Section: Introductionmentioning

confidence: 99%

“…The white‐rot fungus Trametes versicolor is one of the most studied fungi for laccase production. In order to produce laccase, T. versicolor can be cultivated in submerged cultivation or in solid‐state cultivation . Solid‐state fermentation is an old technology that has recently been used for the biological treatment of lignocellulose in the production of value‐added products and for biological pretreatment in biofuel production.…”

Section: Introductionmentioning

confidence: 99%

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Biovalorization of brewers’ spent grain for the production of laccase and polyphenols

et al. 2018

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Brewers’ spent grain (BSG) is the main solid by‐product of the brewing process and is typically disposed of as cattle feed. In this study, BSG was evaluated as a substrate for the production of polyphenols and the lignin‐degrading enzyme laccase using fungal solid‐state fermentation by Trametes versicolor. Laccases are finding increasing applications in the food industry and polyphenols have benefits for human health. After 14 days of fermentation with T. versicolor, there was a 3.4‐fold increase in the extraction of total polyphenols compared with untreated BSG. Using BSG as the sole source of carbon and nitrogen, maximum laccase activity was achieved after seven days of treatment with an activity of 560 U/L. Based on these results, BSG is suggested to be a good lignocellulose waste material to produce value‐added products such as the enzyme laccase and polyphenols. Copyright © 2018 The Institute of Brewing & Distilling

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Section: Resultsmentioning

confidence: 95%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Biovalorization of brewers’ spent grain for the production of laccase and polyphenols

et al. 2018

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“…T. versicolor is known to be a good producer of lignolytic enzymes such as laccase [27] and was chosen for this study due to our previous experience with its solid-state cultivation on corn silage [28,29] and brewery spent grains [30]. The study aims to identify the possible pathways for the utilization of hull-less pumpkin, flax, and hemp oil cakes, before and after biological treatment.…”

Section: Introductionmentioning

confidence: 99%

“…The study aims to identify the possible pathways for the utilization of hull-less pumpkin, flax, and hemp oil cakes, before and after biological treatment. T. versicolor is known to be a good producer of lignolytic enzymes such as laccase [27] and was chosen for this study due to our previous experience with its solid-state cultivation on corn silage [28,29] and brewery spent grains [30]. On the other hand, there is scarce literature data on the use of H. grisea in solid-state fermentation.…”

Section: Introductionmentioning

confidence: 99%

Proximate analysis of cold‐press oil cakes after biological treatment with Trametes versicolor and Humicola grisea

Budžaki

Strelec

Krnić

et al. 2018

Engineering in Life Sciences

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In order to increase the current knowledge on cold‐press oil cakes composition, the present study aims to determine the chemical composition of oil cakes from hull‐less pumpkin (Cucurbita pepo L.), flax (Linum usitatissimum L.), and hemp (Canabis sativa L.) before and after the biological treatment with Trametes versicolor and Humicola grisea using fungal‐based solid‐state technology. After 10 days of treatment, the content of ash, total nitrogen, total proteins, and total organic carbon increased in all the three oil cakes, while the content of ether extracts decreased. After treatment, the concentration of soluble carbohydrates decreased in pumpkin and hemp seed oil cakes, whereas it increased in flaxseed oil cake. During treatment with T. versicolor, the content of fructose significantly increased in hull‐less pumpkin seed oil cake. Fiber content decreased in pumpkin and flaxseed oil cakes after treatment with both of the fungi, whereas it increased in flaxseed oil cake.

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Efficient enzymatic hydrolysis for enriching the antioxidant content of agro‐food industrial residues

Padron‐Regalado,

Mejía‐Olvera,

Marruffo‐Carmona

et al. 2023

JSFA Reports

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BackgroundEnzymatic hydrolysis of agro‐food industrial residues (AFIRs) has the potential of generating great economic value in the food and the cosmetics industry. Here we develop an efficient solid enzymatic hydrolysis (SEH) employing the edible fungus Pleurotus ostreatus to enzymatically digest wheat bran. We assess the antioxidant activity of the SEH product by implementing a highly affordable antioxidant activity test (AAT). Finally, we obtain a tablet formulation containing the SEH product.ResultsResults show that the selected parameters for the SEH are highly competitive among other described SEHs that use fungi to digest wheat residues. The AAT showed a dose‐response antioxidant behavior employing a known antioxidant (vitamin C). The AAT also showed that the SEH product has higher antioxidant activity than the undigested substrate. Finally, the hardness assessment of the SEH tablets suggested changes in stability.ConclusionIn conclusion, an efficient SEH was implemented and its effect on the antioxidant activity was demonstrated. The SEH could be performed at a competitive incubation time, temperature and moisture content. Nevertheless, a deeper study is warranted to fully describe this SEH. We hope that these findings contribute to the development of cost‐efficient SEHs in the food and cosmetics industry.This article is protected by copyright. All rights reserved.

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Recovery of Phenolic Acid and Enzyme Production from Corn Silage Biologically Treated by Trametes versicolor

Cited by 26 publications

References 46 publications

Biovalorization of brewers’ spent grain for the production of laccase and polyphenols

Biovalorization of brewers’ spent grain for the production of laccase and polyphenols

Proximate analysis of cold‐press oil cakes after biological treatment with Trametes versicolor and Humicola grisea

Efficient enzymatic hydrolysis for enriching the antioxidant content of agro‐food industrial residues

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