Kinetic modeling of the simultaneous production of ethanol and fructose by Saccharomyces cerevisiae

Sulieman, Ashraf K; Putra, Meilana Dharma; Abasaeed, Ahmed E; Gaily, Mohamed H; Al-Zahrani, Saeed M; Zeinelabdeen, Mohamed A

Sulieman, Ashraf K; Putra, Meilana Dharma; Abasaeed, Ahmed E; Gaily, Mohamed H; Al-Zahrani, Saeed M; Zeinelabdeen, Mohamed A.

Sulieman, Ashraf K; King Saud University. College of Engineering. Department of Chemical Engineering. Riyadh. SA
Putra, Meilana Dharma; Lambung Mangkurat University. Faculty of Engineering. Chemical Engineering Department. Banjarmasin. ID
Abasaeed, Ahmed E; King Saud University. College of Engineering. Department of Chemical Engineering. Riyadh. SA
Gaily, Mohamed H; King Saud University. College of Engineering. Department of Chemical Engineering. Riyadh. SA
Al-Zahrani, Saeed M; King Saud University. College of Engineering. Department of Chemical Engineering. Riyadh. SA
Zeinelabdeen, Mohamed A; King Saud University. College of Engineering. Department of Chemical Engineering. Riyadh. SA

Electron. j. biotechnol ; 34: 1-8, july. 2018. tab, graf

Article in English | LILACS | ID: biblio-1026812

ABSTRACT

ABSTRACT

Background:

Ethanol and fructose are two important industrial products that enjoy many uses. In this contribution, their production via selective fermentation of date extract using Saccharomyces cerevisiae was studied. Scaling up the process for possible commercialization was investigated in three fermentors with working volume ratio of 140400.

Results:

Higher ethanol concentration was obtained in the larger fermentor due to conversion of fructose. Fructose yields in the 0.5-L, 7.5-L and 80-L fermentors were 99, 92 and 90%, respectively. Good fitting was obtained with the modified Monod kinetics; however, a better fit of cell mass was obtained with the modified GhoseTyagi model which accounts for ethanol inhibition.

Conclusions:

The modified Gompertz model was expanded to facilitate prediction of products' formation and fructose fractions in all three fermentors. Such expansion will be beneficial in industrial applications.

Subject(s)

Saccharomyces cerevisiae/metabolism; Ethanol/chemical synthesis; Fructose/biosynthesis; Yeasts; Kinetics; Bioreactors; Fermentation

Bioreactor; Biosynthesis of ethanol; Ethanol; Fermenters; Fructose; Kinetic modeling; Kinetic models for ethanol biosynthesis; Kinetic models for fructose biosynthesis; Microbiological biosynthesis; Saccharomyces cerevisiae; Yeast

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Full text: Available Index: LILACS (Americas) Main subject: Saccharomyces cerevisiae / Ethanol / Fructose Type of study: Prognostic study Language: English Journal: Electron. j. biotechnol Journal subject: Biotechnology Year: 2018 Type: Article Affiliation country: Indonesia / Saudi Arabia Institution/Affiliation country: King Saud University/SA / Lambung Mangkurat University/ID

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