Abstract
Most biologists agree that at each succeeding level of biological organization new properties appear that would not have been evident by even the most intense and careful examination of lower levels of organization. These levels might be crudely characterized as subcellular, cellular, organ, organism, population, multispecies, community, and ecosystem. The field of ecology developed because even the most meticulous study of single species could not accurately predict how several such species might interact competitively or in predator-prey interactions and the like. Moreover, interactions of biotic and abiotic materials at the level of organization called ecosystem are so complex that they could not be predicted from a detailed examination of isolated component parts. This preamble may seem platitudinous to most biologists who have heard this many times before. This makes it all the more remarkable that in the field of toxicity testing an assumption is made that responses at levels of biological organization above single species can be reliably predicted with single species toxicity tests. Unfortunately, this assumption is rarely explicitly stated and, therefore, often passes unchallenged. When the assumption is challenged, a response is that single species tests have been used for years and no adverse ecosystem or multispecies effects were noted. This could be because single species tests are overly protective when coupled with an enormous application factor or that such effects were simply not detected because there were no systematic, scientifically sound studies carried out to detect them. Probably both of these possibilities occur. However, the important factor is that no scientifically justifiable evidence exists to indicate the degree of reliability with which one may use single species tests to predict responses at higher levels of biological organization. One might speculate that the absence of such information is due to the paucity of reliable tests at higher levels of organization. This situation certainly exists but does not explain the lack of pressure to develop such tests. The most pressing need in the field of toxicity testing is not further perfection of single species tests, but rather the development of parallel tests at higher levels of organization. These need not be inordinately expensive, time consuming, or require any more skilled professionals than single species tests. Higher level tests merely require a different type of biological background. Theoretical ecologists have been notoriously reluctant to contribute to this effort, and, as a consequence, such tests must be developed by this and other organizations with similar interests.
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References
Alloway, B. J. and Davies, B. E.: 1971, ‘Heavy Metal Content of Plants Growing on Soils Contaminated by Lead Mining’, J. Agri. Sci. 76, 321–323.
Cairns, J. Jr., Alexander, M., Cummins, K. W., Edmondson, W. T., Goldman, C. R., Harte, J., Hartung, R., Isensee, A. R., Levins, R., McCormick, J. F., Peterle, T. J., and Zar, J. H.: 1981, Testing for Effects of Chemicals on Ecosystems, National Academy Press, Washington, D.C., 103 pp.
Cairns, J. Jr., Dickson, K. L., and Maki, A. (eds.): 1978, Estimating the Hazard of Chemical Substances to Aquatic Life, American Society for Testing and Materials, Philadelphia, Pa., 278 pp.
Dickson, K. L., Cairns, J. Jr., and Maki, A. (eds.): 1979, Analyzing the Hazard Evaluation Process, American Fisheries Society, Washington, D.C., 159 pp.
Dickson, K. L., Maki, A. W., and Cairns, J. Jr. (eds.): 1982, Modeling for Estimating the Fate of Chemicals in Aquatic Environments, Ann Arbor Science Publishers, Inc., Ann Arbor, Mich.
Doudoroff, P., Anderson, B. G., Burdick, G. E., Galtsoff, P. S., Hart, W. B., Patrick, R., Strong, E. R., Surber, E. W., and Van Horn, W. M.: 1951, ‘Bio-assay for the Evaluation of Acute Toxicity on Industrial Wastes to Fish’, Sewage and Industrial Wastes 23, 1380–1397.
Hart, W. B., Doudoroff, P., and Greenback, J.: 1945, The Evolution of the Toxicity of Industrial Wastes, Chemicals and Other Substances to Freshwater Fishes, Waste Control Laboratory, Atlantic Refining Co., Philadelphia, Pa.
Kimerle, R. A.: 1979, ‘Aquatic Hazard Assessment—Concepts and Application’, in M. P. Bratzel, Jr. (ded.), Workshop on Hazard Assessment, Great Lakes Water Quality Board of the International Joint Commission, Windsor, Ontario, Canada, pp. 221–230.
MacArthur, R., as cited in M. L. Cody and J. M. Diamond (eds.): 1975, Ecology and Evolution of Communities, Belknap Press of Harvard University Press, Cambridge, Mass., 545 pp.
Maki, A. W., Dickson, K. L., and Cairns, J. Jr. (eds.): 1980, Biotransformation and Fate of Chemicals in the Aquatic Environment, American Society for Microbiology, Washington, D.C., 150 pp.
Odum, E. P.: 1981, ‘Revival of Non-Laboratory Science’, Association of Southeastern Biologists Bulletin 28, No. 3, pp. 119–121.
Patrick, R.: 1949, ‘A proposed Biological Measure of Stream Conditions, Based on a Survey of the Conestoga Basin, Lancaster County, Pennsylvania’, Proceedings of the Academy of Natural Science of Philadelphia 101, 277–341.
Vannote, R. L., Minshall, G. W., Cummins, K. W., Sedell, J. R., and Cushing, C. E.: 1980, ‘The River Continuum Concept’, Canadian Journal of Fisheries and Aquatic Sciences 37, 130–137.
Vogl, R. J.: 1979, ‘The Ecological Factors that Produce Perturbation-Dependent Ecosystems’, in J. Cairns Jr. (ed.), The Recovery Process in Damaged Ecosystems, Ann Arbor Science Publishers, Inc., Ann Arbor, Mich., pp. 63–94.
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Cairns, J. Are single species toxicity tests alone adequate for estimating environmental hazard?. Environ Monit Assess 4, 259–273 (1984). https://doi.org/10.1007/BF00394145
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DOI: https://doi.org/10.1007/BF00394145