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Statements

Subject Item
n2:RIV%2F67985858%3A_____%2F04%3A00105036%21RIV%2F2005%2FAV0%2FA27005%2FN
rdf:type
skos:Concept n17:Vysledek
dcterms:description
In the continuous systems, such as continuous beer fermentation, immobilized cells are kept inside the bioreactor for long periods of time. Thus an important factor in the design and performance of the immobilized yeast reactor is immobilized cell viability and physiology. A mathematical model of the immobilized yeast biofilm growth on the surface of spent grain particles based on cell deposition, immobilized cell growth, and immobilized biomass detachment was formulated. The concept of the active fraction of immobilized biomass and the maximum attainable biomass load was included into the model. The model successfully predicted the dynamics of the immobilized cell growth, maximum biomass load, free cell growth, and glucose consumption under constant hydrodynamic conditions in a bubble-column reactor. Good agreement between model simulations and experimental data was achieved. Byl vytvořen matematický model růstu biofilmu na povrchu mláta založený na adhezi buněk k nosiči, vzájemné adhezi buněk, růstu imobilizovaných buněk a vyrůstání buněk mimo biofilm. Do modelu byl zahrnut kocept aktivní frakce imobilizované biomasy a maximální dosažitelné koncentrace buněk v biofilmu. Vzhledem k tomu, že maximální tlouštka biofilmu byla 10 mikrometrů , limitace v důsledku difuze subsrátu uvnitř biofilmu byla zanedbána. Model dobře popisuje dynamiku růstu biofilmu, maximální množství buněk v biofilmu a spotřebu glukozy za konstatních hydrodynamických podmínek v probublavaném reaktoru. In the continuous systems, such as continuous beer fermentation, immobilized cells are kept inside the bioreactor for long periods of time. Thus an important factor in the design and performance of the immobilized yeast reactor is immobilized cell viability and physiology. A mathematical model of the immobilized yeast biofilm growth on the surface of spent grain particles based on cell deposition, immobilized cell growth, and immobilized biomass detachment was formulated. The concept of the active fraction of immobilized biomass and the maximum attainable biomass load was included into the model. The model successfully predicted the dynamics of the immobilized cell growth, maximum biomass load, free cell growth, and glucose consumption under constant hydrodynamic conditions in a bubble-column reactor. Good agreement between model simulations and experimental data was achieved.
dcterms:title
Růstový model a a metabolická aktivita biofilmu z pivovarských kvasinek na povrchu mláta: Biokatalyzátor pro kontinuální fermentaci piva Growth Model and Metabolic Activity of Brewing Yeast Biofilm on the Surface of Spent Grains: A Biocatalyst for Continuous Beer Fermentation Growth Model and Metabolic Activity of Brewing Yeast Biofilm on the Surface of Spent Grains: A Biocatalyst for Continuous Beer Fermentation
skos:prefLabel
Růstový model a a metabolická aktivita biofilmu z pivovarských kvasinek na povrchu mláta: Biokatalyzátor pro kontinuální fermentaci piva Growth Model and Metabolic Activity of Brewing Yeast Biofilm on the Surface of Spent Grains: A Biocatalyst for Continuous Beer Fermentation Growth Model and Metabolic Activity of Brewing Yeast Biofilm on the Surface of Spent Grains: A Biocatalyst for Continuous Beer Fermentation
skos:notation
RIV/67985858:_____/04:00105036!RIV/2005/AV0/A27005/N
n5:strany
1733;1740
n5:aktivita
n11:Z
n5:aktivity
Z(AV0Z4072921), Z(MSM 223300005)
n5:cisloPeriodika
20
n5:dodaniDat
n8:2005
n5:domaciTvurceVysledku
n16:9807616 n16:8241066
n5:druhVysledku
n14:J
n5:duvernostUdaju
n10:S
n5:entitaPredkladatele
n6:predkladatel
n5:idSjednocenehoVysledku
565824
n5:idVysledku
RIV/67985858:_____/04:00105036
n5:jazykVysledku
n15:eng
n5:klicovaSlova
growth model;beer fermentation;immobilized cells
n5:klicoveSlovo
n9:immobilized%20cells n9:growth%20model n9:beer%20fermentation
n5:kodStatuVydavatele
US - Spojené státy americké
n5:kontrolniKodProRIV
[E61C08C3824F]
n5:nazevZdroje
Biotechnology Progress
n5:obor
n12:CE
n5:pocetDomacichTvurcuVysledku
2
n5:pocetTvurcuVysledku
6
n5:rokUplatneniVysledku
n8:2004
n5:svazekPeriodika
6
n5:tvurceVysledku
Kuncová, Gabriela Dostálek, P. Brányik, T. Podrazký, Ondřej Vicente, A. A. Teixeira, J. A.
n5:zamer
n7:AV0Z4072921 n7:MSM%20223300005
s:issn
8756-7938
s:numberOfPages
8