Physical Properties of Cell Water in Partially Dried Saccharomyces cerevisiae

Koga, Shozo; Echigo, Akira; Nunomura, Kazuko

doi:10.1016/s0006-3495(66)86685-7

Cited by 49 publications

(13 citation statements)

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“…1 and 3). The moisture levels of commercial active dry yeasts are never lower than 5-8%, since irreversible damage to metabolic functions occurs by further removal of chemically bound water [15]. The electron micrographs of the dried biocatalyst (Fig.…”

Section: Low-temperature Thermal Drying Of Immobilized Yeastmentioning

confidence: 99%

Fermentation Efficiency of Cells Immobilized on Delignified Brewers' Spent Grains after Low- and High-Temperature Thin Layer Thermal Drying

Tsaousi

Κουτίνας

Bekatorou

et al. 2009

Appl Biochem Biotechnol

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Low-cost dried yeasts immobilized on delignified brewers' spent grains for use in wine making and brewing were produced by simple thermal drying techniques. To optimize the thermal drying process, vacuum and air stream conditions were examined. Drying of thin layers of the biocatalysts was performed at low (30-38 degrees C) and high temperatures (40-70 degrees C). The fermentation efficiency of the thermally dried biocatalysts was acceptable, with immobilized cells showing a significantly higher thermotolerance compared with free cells. Immobilized cells dried at high temperatures presented slightly improved glucose fermentation efficiency compared with the low-temperature dried biocatalysts. Gas chromatography-mass spectrometry analysis of aroma volatiles of the fermented products revealed an increase of esters, lower higher alcohol formation, and significantly lower concentration of carbonylic compounds.

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Section: Low-temperature Thermal Drying Of Immobilized Yeastmentioning

confidence: 99%

Fermentation Efficiency of Cells Immobilized on Delignified Brewers' Spent Grains after Low- and High-Temperature Thin Layer Thermal Drying

Tsaousi

Κουτίνας

Bekatorou

et al. 2009

Appl Biochem Biotechnol

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“…The respiration rate of the yeast cells starts at h % 0.20 g g À1 and increases linearly with water content. [7] Seeds of plants may stay in the dehydrated state for years, but germinate promptly upon hydration. The rate of O 2 consumption increases in a stepwise manner at some critical hydration level (from h % 0.14 g g À1 for apples to h % 0.26 g g À1 for peas).…”

Section: The Effect Of Hydrationmentioning

confidence: 99%

Which Properties of a Spanning Network of Hydration Water Enable Biological Functions?

Brovchenko¹,

Oleinikova²

2008

ChemPhysChem

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The central role of water in biological functions is well-recognized, but numerous questions concerning the physical mechanisms behind the importance of water for life remain unanswered. Water in biosystems exists mainly as hydration water. Analysis of the phase diagram of hydration water shows that biological functions are possible only when the surfaces of biomolecules are covered by spanning hydrogen-bonded networks of hydration water. The comparative studies of the various properties of hydrated biosystems in the presence and in the absence of a spanning water network should clarify its specific physical properties, which are crucial for biological functions. Herein, we summarize the recent progress in these studies. The biological activity of the living organisms is maximal in a narrow temperature interval, where the spanning network of hydration water breaks up with heating via a percolation transition. The entropy of the hydration water related to the diversity of cluster size diverges at this percolation threshold. The possible role of this phenomenon in life processes is discussed.

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“…is not in equilibrium with the free cytoplasmic water. A further 0.05 g/g is similarly bound but exhibits some slow exchange, a further 0.1 g/g behaving as a gel domain while the remainder, 0.55 g/g, behaves as free water [94]. The rate of respiration decreases as the water content decreases and at 0.2 g water/g dry weight it ceases, i.e.…”

Section: Exclusion Of Solutes From the Cytoplasmmentioning

confidence: 99%

“…The rate of respiration decreases as the water content decreases and at 0.2 g water/g dry weight it ceases, i.e. the non-exchangeable + limited rotational + gel domain water does not act to support metabolic activity -it is functionally unavailable [94].…”

Section: Exclusion Of Solutes From the Cytoplasmmentioning

confidence: 99%

Intracellular ethanol â accumulation and exit from yeast and other cells

Jones¹

1988

FEMS Microbiology Letters

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Physical Properties of Cell Water in Partially Dried Saccharomyces cerevisiae

Cited by 49 publications

References 0 publications

Fermentation Efficiency of Cells Immobilized on Delignified Brewers' Spent Grains after Low- and High-Temperature Thin Layer Thermal Drying

Fermentation Efficiency of Cells Immobilized on Delignified Brewers' Spent Grains after Low- and High-Temperature Thin Layer Thermal Drying

Which Properties of a Spanning Network of Hydration Water Enable Biological Functions?

Intracellular ethanol â accumulation and exit from yeast and other cells

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Physical Properties of Cell Water in Partially Dried Saccharomyces cerevisiae

Cited by 49 publications

References 0 publications

Fermentation Efficiency of Cells Immobilized on Delignified Brewers' Spent Grains after Low- and High-Temperature Thin Layer Thermal Drying

Fermentation Efficiency of Cells Immobilized on Delignified Brewers' Spent Grains after Low- and High-Temperature Thin Layer Thermal Drying

Which Properties of a Spanning Network of Hydration Water Enable Biological Functions?

Intracellular ethanol â accumulation and exit from yeast and other cells

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Product

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Intracellular ethanol â accumulation and exit from yeast and other cells