Inhibitory action of toxic compounds present in lignocellulosic hydrolysates on xylose to xylitol bioconversion by Candida guilliermondii

Pereira, Rogério Santos; Mussatto, Solange I.; Roberto, Inês Conceição

doi:10.1007/s10295-010-0830-6

Cited by 43 publications

(35 citation statements)

References 22 publications

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“…3), and it inhibits cellulose hydrolysis in wet cake by endo-and exo-cellulases, and cellobiose hydrolysis by beta-glucosidase (77). The inhibitory effect of on metabolism of Candida guilliermondii yeast during xylose to xylitol bioconversion was evaluated and concluded that syringaldehyde may affect cell growth and metabolism of this organism (78). Furthermore, the inhibitory effects of syringaldehyde on a fermentation by Saccharomyces cerevisiae K35 was investigated and it was found that concentrations higher than 5 g/L of syringaldehyde were toxic (79).…”

Section: Phenolic Aldehydes Resulting From Lignin Hydrolysismentioning

confidence: 99%

Biological activities of lignin hydrolysate-related compounds

Lee¹,

Monnappa²,

Mitchell³

2012

BMB Reports

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Section: Phenolic Aldehydes Resulting From Lignin Hydrolysismentioning

confidence: 99%

Biological activities of lignin hydrolysate-related compounds

Lee¹,

Monnappa²,

Mitchell³

2012

BMB Reports

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“…Furfural, the dehydration product of pentoses, was commonly found in hemicellulose hydrolysis [6]. Pereira et al [7] reported that the inhibitors of acetic acid, ferulic acid, and syringaldehyde in fermentation substrate would affect microbial cell growth, xylose consumption, and xylitol yield during microbial fermentation for xylitol production. The toxicity of acetic acid was more severe under low pH conditions than under high pH conditions [8, 9].…”

Section: Introductionmentioning

confidence: 99%

Detoxification of Corncob Acid Hydrolysate with SAA Pretreatment and Xylitol Production by ImmobilizedCandida tropicalis

Deng

Tang

Liu

2014

The Scientific World Journal

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Xylitol fermentation production from corncob acid hydrolysate has become an attractive and promising process. However, corncob acid hydrolysate cannot be directly used as fermentation substrate owing to various inhibitors. In this work, soaking in aqueous ammonia (SAA) pretreatment was employed to reduce the inhibitors in acid hydrolysate. After detoxification, the corncob acid hydrolysate was fermented by immobilized Candida tropicalis cell to produce xylitol. Results revealed that SAA pretreatment showed high delignification and efficient removal of acetyl group compounds without effect on cellulose and xylan content. Acetic acid was completely removed, and the content of phenolic compounds was reduced by 80%. Furthermore, kinetic behaviors of xylitol production by immobilized C. tropicalis cell were elucidated from corncob acid hydrolysate detoxified with SAA pretreatment and two-step adsorption method, respectively. The immobilized C. tropicalis cell showed higher productivity efficiency using the corncob acid hydrolysate as fermentation substrate after detoxification with SAA pretreatment than by two-step adsorption method in the five successive batch fermentation rounds. After the fifth round fermentation, about 60 g xylitol/L fermentation substrate was obtained for SAA pretreatment detoxification, while about 30 g xylitol/L fermentation substrate was obtained for two-step adsorption detoxification.

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“…If the employed yeast strain exhibits rather good tolerance to toxic substances, the complete removal of toxic compounds from the fermentation medium is not necessary (37) ; in fact, some toxic substances at low concentrations may even be beneficial to xylitol production. These yeasts exhibit good activity in degrading toxic substances and many small molecule impurities (acetic acid, furfural, phenol), which significantly improves xylitol fermentative production performance and effectively reduces the burden of physical and chemical purification or detoxification processes.…”

Section: Hydrolysis Of Biomassmentioning

confidence: 99%

Xylitol Biological Production: A Review of Recent Studies

Mohamad

Kamal

Mokhtar

2014

Food Reviews International

110

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Xylitol is an alternative sweetener that is recommended for use in food and pharmaceutical products, as it has some health benefits. It is currently produced on a large scale using a chemical reduction that requires high energy and is costly. Biological conversion of xylitol using microorganisms is an alternative process that is environmentally friendly and cost-effective. This process has been studied in an effort to provide one that is high yielding and competitive with chemical processes. This article reviews recent studies in the development of biological conversion processes for the production of xylitol, including biomass conversion, fermenting microorganisms, and new technology for full-scale process development.

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Inhibitory action of toxic compounds present in lignocellulosic hydrolysates on xylose to xylitol bioconversion by Candida guilliermondii

Cited by 43 publications

References 22 publications

Biological activities of lignin hydrolysate-related compounds

Biological activities of lignin hydrolysate-related compounds

Detoxification of Corncob Acid Hydrolysate with SAA Pretreatment and Xylitol Production by ImmobilizedCandida tropicalis

Xylitol Biological Production: A Review of Recent Studies

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