Effects of helium group gases and nitrous oxide on hela cells

Bruemmer, Joseph H.; Brunetti, B. B.; Schreiner, H. R.

doi:10.1002/jcp.1040690315

Cited by 20 publications

(5 citation statements)

References 9 publications

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“…Taylor (20) found that even highly compressed He at 50 MPa was able to reduce the inhibitory effect of 50 MPa of hydrostatic pressure for growth of a marine pseudomonad. The studies of Bruemmer et al (2) with HeLa cells in monolayer culture indicated little inhibitory effect of He, Ne, or N2 except at pressures above ca 5 MPa. Ar caused a 25% reduction in cell count at a pressure ca.…”

Section: Discussionmentioning

confidence: 92%

Microbial Growth Modification by Compressed Gases and Hydrostatic Pressure

Thom

Marquis

1984

Appl Environ Microbiol

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Studies of the growth-modifying actions for Escherichia coli, Saccharomyces cerevisiae, and Tetrahymena thermophila of helium, nitrogen, argon, krypton, xenon, and nitrous oxide led to the conclusion that there are two definable classes of gases. Class 1 gases, including He, N2, and Ar, are not growth inhibitors; in fact, they can reverse the growth inhibitory action of hydrostatic pressures. Class 2 gases, including Kr, Xe, and N20, are potent growth inhibitors at low pressures. For example, at 24°C, 50% growth-inhibitory pressures of N20 were found to be ca. 1.7 MPa for E. coli, 1.0 MPa for S. cerevisiae, and 0.5 MPa for T. thermophila. Class 1 gases could act as potentiators for growth inhibition by N2O, O, Kr, or Xe. Hydrostatic pressure alone is known to reverse N20 inhibition of growth, but we found that it did not greatly alter oxygen toxicity. Therefore, potentiation by class 1 gases appeared to be a gas effect rather than a pressure effect. The temperature profile for growth inhibition of S. cerevisiae by N2O revealed an optimal temperature for cell resistance of ca. 24°C, with lower resistance at higher and lower temperatures. Overall, it appeared that microbial growth modification by hyperbaric gases could not be related to their narcotic actions but reflected definably different physiological actions.

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Section: Discussionmentioning

confidence: 92%

Microbial Growth Modification by Compressed Gases and Hydrostatic Pressure

Thom

Marquis

1984

Appl Environ Microbiol

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“…The inactive gas (He) that was used for preservation has anesthetic action (8) and metabolic suppression action (3), and inactive gases such as Xe are used for preserving plants (31).…”

Section: Discussionmentioning

confidence: 99%

Seventy-Two-Hour Preservation, Resuscitation, and Transplantation of an Isolated Rat Heart with High Partial Pressure Carbon Monoxide Gas (PCO = 400 hPa) and High Partial Pressure Carbon Dioxide (PCO₂ = 100 hPa)

Hatayama¹,

Yoshida²,

Seki³

2010

Cell Transplant

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The cardiac cavity of an isolated rat heart was filled with a Krebs-Henseleit (KH) solution, and the heart was hung in a high-pressure chamber. After the high-pressure chamber had been filled with a mixed gas (PCO = 400 hPa, PCO(2) = 100 hPa, PO(2) = 900 hPa, PHe = 5600 hPa) and preserved for 72 h, we performed a cervical ectopic heart transplantation on a recipient rat and resuscitated the preserved heart. This is the first incidence in the world of a mammalian organ having been successfully preserved and resuscitated after 72 h via a desiccation method.

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“…Theories regarding the mechanisms of these effects of CO 2 include theories that it is adsorbed on the surface of a protein biopolymer (14) or theories that the main cause of the effects is that it structures collections of water molecules in living organisms (24), just like inert gases such as Xe that are, just like CO 2 , used for their anesthetic mechanism (7), their decomposition-inhibiting mechanism (3), or for the preservation of plants (28). In addition, it is believed that decreases in pH that occur with the dissolution of CO 2 are also involved, although this has yet to be fully understood.…”

Section: Discussionmentioning

confidence: 99%

A Study on the Perfusion Preservation, Resuscitation, and Transplantation of a Rat Heart Isolated for 96 Hours

2009

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Krebs-Henseleit (KH) solution was used to fill the heart chamber of an isolated rat heart before it was immersed in perfluorocarbon (PFC), which is an inert fluid. A gas mixture (PCO(2) = 150 hPa and PO(2) = 850 hPa) was then aerated at a constant rate into the PFC solution, and the isolated heart was thereafter preserved for 96 h with KH solution perfused continuously at a rate of 0.1 ml/h from the aorta of the isolated heart through a cannula. After preservation, the preserved heart was heterotopically transplanted into the neck of a recipient rat and then it was resuscitated. Using this method for preserving mammalian organs, we attained reproducibility after perfusion preservation for 96 h.

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Effects of helium group gases and nitrous oxide on hela cells

Cited by 20 publications

References 9 publications

Microbial Growth Modification by Compressed Gases and Hydrostatic Pressure

Microbial Growth Modification by Compressed Gases and Hydrostatic Pressure

Seventy-Two-Hour Preservation, Resuscitation, and Transplantation of an Isolated Rat Heart with High Partial Pressure Carbon Monoxide Gas (PCO = 400 hPa) and High Partial Pressure Carbon Dioxide (PCO₂ = 100 hPa)

A Study on the Perfusion Preservation, Resuscitation, and Transplantation of a Rat Heart Isolated for 96 Hours

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Effects of helium group gases and nitrous oxide on hela cells

Cited by 20 publications

References 9 publications

Microbial Growth Modification by Compressed Gases and Hydrostatic Pressure

Microbial Growth Modification by Compressed Gases and Hydrostatic Pressure

Seventy-Two-Hour Preservation, Resuscitation, and Transplantation of an Isolated Rat Heart with High Partial Pressure Carbon Monoxide Gas (PCO = 400 hPa) and High Partial Pressure Carbon Dioxide (PCO2 = 100 hPa)

A Study on the Perfusion Preservation, Resuscitation, and Transplantation of a Rat Heart Isolated for 96 Hours

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Seventy-Two-Hour Preservation, Resuscitation, and Transplantation of an Isolated Rat Heart with High Partial Pressure Carbon Monoxide Gas (PCO = 400 hPa) and High Partial Pressure Carbon Dioxide (PCO₂ = 100 hPa)