Hostname: page-component-78c5997874-ndw9j Total loading time: 0 Render date: 2024-11-05T14:22:07.161Z Has data issue: false hasContentIssue false

The accumulation of 137Cs by brackish water invertebrates and its relation to the regulation of potassium and sodium

Published online by Cambridge University Press:  11 May 2009

G. W. Bryan
Affiliation:
The Plymouth Laboratory

Extract

The relationship between the ability of brackish water invertebrates to regulate Na and K and the extent to which the radioactive fission product 137Cs can be accumulated has been studied.

The brackish water isopod Sphaeroma hookeri and the gastropod Potamopyrgus jenkinsi have been acclimatised to a wide range of sea-water dilutions. Unfed Sphaeroma can survive in sea-water concentrations of 100–2·5%, while Potamopyrgus can live fairly indefinitely in concentrations of 50–0·1%. Measurements of Na and K in the whole animals of both species and in the blood of Sphaeroma have been made. Salt movements are quite rapid and acclimatization to new media is achieved by both species in less than 10 h. Concentration factors for inactive K in particular increase to high values in the more dilute media.

Uptake of the isotopes 42K and 137Cs from solution has been examined in both species over a range of sea-water concentrations. All of the body K is exchangeable with 42K and in Sphaeroma exchange of 42K between the blood and tissues is so rapid that the body surface appears to be the limiting factor in the uptake of the isotope. Both species exchange 42K more rapidly in the higher concentrations of sea water and one reason for this may be the existence of an exchange diffusion component of exchange which increases as the salinity of the medium is raised. Indirect evidence suggests that the excretion of 42K in urine is probably not an important factor in exchange.

Type
Research Article
Copyright
Copyright © Marine Biological Association of the United Kingdom 1963

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Bryan, G. W., 1960. Sodium regulation in the crayfish Astacus fluviatilis. I. The normal animal. J. exp. Biol., Vol. 37, pp. 8399.CrossRefGoogle Scholar
Bryan, G. W., 1961. The accumulation of radioactive caesium in crabs. J. mar. biol. Ass. U.K., Vol. 41, pp. 551–75.CrossRefGoogle Scholar
Bryan, G. W., 1963. The accumulation of radioactive caesium by marine invertebrates. J. mar. biol. Ass. U.K., Vol. 43, pp. 519539.CrossRefGoogle Scholar
Bryan, G. W. & Ward, E., 1962. Potassium metabolism and the accumulation of 137caesium by decapod Crustacea. J. mar. biol. Ass. U.K., Vol. 42, pp. 199241.CrossRefGoogle Scholar
Croghan, P. C., 1958. Ionic fluxes in Anemia salina (L.). J. exp. Biol., Vol. 35, pp. 425–36.CrossRefGoogle Scholar
Lockwood, A. P. M., 1959. The osmotic and ionic regulation of Asellus aquaticus L. J. exp. Biol., Vol. 365 pp. 546–55.CrossRefGoogle Scholar
Lockwood, A. P. M., 1961. The urine of Gammarus duebeni and G. pulex. J. exp. Biol., Vol. 38, pp. 647–58.Google Scholar
Lockwood, A. P. M. & Croghan, P. C., 1957. The chloride regulation of the brackish and fresh water races of Mesidotea entomon (L.). J. exp. Biol., Vol. 34, pp. 253–58.CrossRefGoogle Scholar
Neumann, D., 1960. Osmotische Resistenz und Osmoregulation der Flussdeckelschnecke Theodoxus fluviatilis L. Biol. Zbl., Vol. 79, pp. 585605.Google Scholar
Parry, G., 1953. Osmotic and ionic regulation in the isopod crustacean Ligia oceanica. J. exp. Biol., Vol. 30, pp. 567–74.Google Scholar
Picken, L. E. R., 1937. The mechanism of urine formation in invertebrates. II. The excretory mechanisms in certain Mollusca. J. exp. Biol., Vol. 14, pp. 2034.CrossRefGoogle Scholar
Riegel, J. A., 1959. Some aspects of osmoregulation in two species of sphaeromid isopod Crustacea. Biol. Bull., Woods Hole, Vol. 116, pp. 272–84.CrossRefGoogle Scholar
Shaw, J., 1955. Ionic regulation in the muscle fibres of Carcinus maenas. II. The effect of reduced blood concentration. J. exp. Biol., Vol. 32, pp. 664–80.CrossRefGoogle Scholar
Shaw, J. & Sutcliffe, D. W., 1961. Studies on sodium balance in Gammarus duebeni Lilljeborg and G. pulex pulex (L.). J. exp. Biol., Vol. 38, pp. 116.CrossRefGoogle Scholar
Smales, A. A. & Salmon, L., 1955. Determination by radioactivation of small amounts of rubidium and caesium in sea-water and related materials of geochemical interest. Analyst, Vol. 80, pp. 3750.CrossRefGoogle Scholar