Satoshi Kawachi scite author profile

The inhibitory action of compressed hydrocarbon gases on the growth of the yeast Saccharomyces cerevisiae was investigated quantitatively by microcalorimetry. Both the 50% inhibitory pressure (IP(50)) and the minimum inhibitory pressure (MIP), which are regarded as indices of the toxicity of hydrocarbon gases, were determined from growth thermograms. Based on these values, the inhibitory potency of the hydrocarbon gases increased in the order methane << ethane < propane < i-butane < n-butane. The toxicity of these hydrocarbon gases correlated to their hydrophobicity, suggesting that hydrocarbon gases interact with some hydrophobic regions of the cell membrane. In support of this, we found that UV absorbing materials at 260 nm were released from yeast cells exposed to compressed hydrocarbon gases. Additionally, scanning electron microscopy indicated that morphological changes occurred in these cells.

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Effects of compressed unsaturated hydrocarbon gases on yeast growth

Kawachi

Arao

Suzuki

et al. 2010

Annals of the New York Academy of Sciences

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The effect of compressed unsaturated hydrocarbon gases on the growth of the yeast Saccharomyces cerevisiae was investigated by microcalorimetry. The growth thermograms showed that unsaturated hydrocarbon gases inhibited yeast growth. As an approach to determining the comparative toxicity of unsaturated hydrocarbon gases, we determined the 50% inhibitory pressure (IP(50)) and the minimum inhibitory pressure (MIP). On the basis of the IP(50) and MIP values, the inhibitory potency of the gases increased in the order ethylene < propylene < 1-butene. Additionally, scanning electron microscopy showed that cells treated with unsaturated hydrocarbon gases were damaged, including invagination of the cell surface.

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Technological competitiveness in the chemical industry

Kawachi¹

2003

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Effects of compression with ethane, ethylene and their fluorinated derivatives on yeast growth

Kawachi

Arao

Hara

et al. 2010

J. Phys.: Conf. Ser.

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Satoshi Kawachi

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Effects of compressed unsaturated hydrocarbon gases on yeast growth

Technological competitiveness in the chemical industry

Effects of compression with ethane, ethylene and their fluorinated derivatives on yeast growth

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