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Potassium and Water Distribution in Depression

Published online by Cambridge University Press:  29 January 2018

David Murray Shaw  and
Alec Coppen
David Murray Shaw
Affiliation:
M.R.C. Neuropsychiatric Research Unit, Carshalton and West Park Hospital, Epsom, Surrey
Alec Coppen
Affiliation:
M.R.C. Neuropsychiatric Research Unit, Carshalton and West Park Hospital, Epsom, Surrey
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Extract

The ionic theory of cell excitability shows how impulses are generated, conducted and propagated by movements of ions between the cells and the extracellular fluid. It is known that changes in the concentration of sodium and potassium in either the extracellular water (E.C.W.) or the intracellular water (I.C.W.) may have a marked effect on the resting and action potentials of excitable cells. If affective disorders are manifestations of complex but reversible changes in brain excitability, hen these in turn might be caused by alterations in the concentration of electrolytes within the cells of the central nervous system (C.N.S.). Although it is not possible to measure the distribution of electrolytes specifically in the C.N.S. in man, it is possible to measure their distribution in the body as a whole. In previous papers we have shown that residual sodium (intracellular plus a small quantity of bone sodium) is increased by 50 per cent. in depression (Coppen and Shaw, 1963) and by nearly 200 per cent. in mania (Coppen, Shaw, Malleson and Costain, 1965). The present paper shows that there are also abnormalities in the distribution of potassium, the other main cation determining cell excitability, in patients suffering from severe depression.

Type
Research Article
Information
The British Journal of Psychiatry , Volume 112 , Issue 484 , March 1966 , pp. 269 - 276
Copyright
Copyright © Royal College of Psychiatrists, 1966 

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References

Anderson, E. C. (1963). “Three component body composition analysis based on potassium and water determinations.” Ann. N.Y. Acad. Sci., 110, 189212.CrossRefGoogle Scholar
Challenger, J. M., and Leyton, G. B. (1964). “Blood pH and plasma p CO2 in mental disease.” Brit. J. Psychiat., 110, 9597.Google Scholar
Coppen, A. J., and Shaw, D. M. (1963). “Mineral metabolism in melancholia.” Brit. med. J., ii, 1439–44.Google Scholar
Coppen, A. J., Shaw, D. M., Malleson, A., and Costain, R. (1966). “Mineral metabolism in mania.” Ibid. i, 7175.Google Scholar
Lindegård, B. (1953). “Variations in body build. A somatometric and X-ray cephalometric investigation in Scandinavian adults.” Acta Psychiat. Neurol. Scand., Suppl. 86.Google Scholar
Maycock, G., Terry, S. W., Vennart, J., Wise, M. E. (1960). “Measurements of caesium-137 in human beings during 1958–1959.” Nature (Lond.), 188, 355.Google Scholar
Moore, F. D., Olesen, K. H., McMurrey, J. D., Parker, H. V., Ball, M. R., and Boyden, C. M. (1963). The Body Cell Mass and Its Supporting Environment. Philadelphia: Saunders.Google Scholar
Remenchik, A. P., and Miller, C. E. (1962). Whole Body Counting. Vienna: International Atomic Energy Agency.Google Scholar
Veall, N., and Vetter, H. (1958). Radioisotope Techniques in Clinical Research and Diagnosis. London: Butterworths.Google Scholar
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