Pauling and Miller have independently proposed that the presence of an anesthetic gas in tissue induces a cage-like arrangement of hydrogen-bonded water molecules. The theories recognize that most gas-hydrate crystals would not form at the temperature and pressure that exist during anesthesia and propose that other components of tissue such as protein should have a stabilizing effect. Measurements of the behavior of water, rather than the anesthetic agent, would provide alternative information about the likelihood of hydrate crystal formation and this information could be such as to be applicable to body temperature and to pressures used for anesthesia. If the number of hydrogen-bonded water molecules in tissue is increased, then the movement of an average water molecule should be hindered. Movement of water through the tissue may be measured by tagging it with tritium and the anesthetic gas should then slow the movement of tritiated water through the tissue. The flux of tritiated water through rat cecum is indeed slowed when the cecum is exposed to the anesthetic gas, xenon, which can participate biochemically only by virtue of its van der Waals interaction. The decrement in water flux is in reasonable agreement with what could be expected theoretically from calculations based on the activation energy for the self-diffusion of water and the degree of hypothermia necessary to produce narcosis.
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1 December 1968
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December 01 1968
Anesthetic Gases and Water Structure : The effect of xenon on tritiated water flux across the gut
Eugene Y. Berger,
Eugene Y. Berger
From the Department of Medicine, New York University School of Medicine 10016, and the New York University Research Service, Goldwater Memorial Hospital, Welfare Island, New York 10017
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F. Rene Pecikyan,
F. Rene Pecikyan
From the Department of Medicine, New York University School of Medicine 10016, and the New York University Research Service, Goldwater Memorial Hospital, Welfare Island, New York 10017
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Grace Kanzaki
Grace Kanzaki
From the Department of Medicine, New York University School of Medicine 10016, and the New York University Research Service, Goldwater Memorial Hospital, Welfare Island, New York 10017
Search for other works by this author on:
Eugene Y. Berger
From the Department of Medicine, New York University School of Medicine 10016, and the New York University Research Service, Goldwater Memorial Hospital, Welfare Island, New York 10017
F. Rene Pecikyan
From the Department of Medicine, New York University School of Medicine 10016, and the New York University Research Service, Goldwater Memorial Hospital, Welfare Island, New York 10017
Grace Kanzaki
From the Department of Medicine, New York University School of Medicine 10016, and the New York University Research Service, Goldwater Memorial Hospital, Welfare Island, New York 10017
Received:
March 27 1968
Online ISSN: 1540-7748
Print ISSN: 0022-1295
Copyright © 1968 by The Rockefeller University Press
1968
J Gen Physiol (1968) 52 (6): 876–886.
Article history
Received:
March 27 1968
Citation
Eugene Y. Berger, F. Rene Pecikyan, Grace Kanzaki; Anesthetic Gases and Water Structure : The effect of xenon on tritiated water flux across the gut . J Gen Physiol 1 December 1968; 52 (6): 876–886. doi: https://doi.org/10.1085/jgp.52.6.876
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