Abstract
Community structure or species composition of benthic invertebrates has frequently been used in environmental monitoring and assessment of aquatic systems. Three general approaches have been taken: the ‘saprobic’ approach, which requires detailed knowledge of taxonomy and is most effective in measuring impacts from sewage effluents; diversity indices, which do not require detailed knowledge of species requirements but ignore information provided by important species and tend to lose information; and biotic indices, which combine both approaches. In the past few years considerable advances have been made by applying multivariate statistical techniques to large data matrices and relating benthic community structure to key environmental variables. Using these techniques it is possible to establish reference communities for a set of environmental conditions, to predict the benthic community that should occur at new sites and thus measure deviation from an expected community type. This suggests that environmental criteria and objectives can be established based on biological variables as opposed to the more traditional chemical approach.
Measurement of ecosystem health using functional attributes of benthic invertebrates is generally in the development stage. In the future, functional measures of ecosystem health, such as chronic measures of toxicity or stress, should be incorporated into any assessment process.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Armitage, P. D., D., Moss, J. F., Wright & M. T., Furse, 1983. The performance of a new biological water quality score system based on macroinvertebrates over a wide range of unpolluted running-water sites. Water Res. 17: 333–347.
Basaguren, A. & E., Orive, 1990. The relationship between water quality and caddisfly assemblage structure in fast-running rivers. The River Cadagua basin. Environ. Monit. Assess. 15: 35–48.
Brock, D. A., 1977. Comparison of community similarity indexes. J. Water Pollut. Control Fed. 49: 2488–2494.
Butler, G. C., B. G., Bennett, D. R., Miller, J. K., Piotrowski & A., Sors, 1985. Methods for estimating exposure to chemicals. In: V.B., Vouk, G.C., Butler, D.G., Hoel & D.B., Peakall (eds),Methods for Estimating Risk of Chemical Injury: Human and Non-human Biota and Ecosystems. pp. 7–28. John Wiley & Sons, New York.
Cairns, J.Jr, 1981. Biological monitoring. Part VI — Future needs. Water Res. 15: 941–952.
Cairns, J.Jr & W. H.van der, Schalie, 1980. Biological monitoring. Part I — Early warning systems. Water Res. 14: 1179–1196.
Cairns, J.Jr, D. L., Kuhn & J. L., Plafkin, 1979. Protozoan Colonization of Artificial Substrates. In: R.L., Wetzel (ed.),Methods and Measurements of Attached Microcommunities: A Review. Amer. Soc. Test. Materials, Philadelphia, PA.
Calow, P., 1989. The choice and implementation of environmental bioassays. Hydrobiologia 188/189: 61–64.
Chapman, P. M. & E. R., Long, 1983. The use of bioassays as part of a comprehensive approach to marine pollution assessment. Mar. Pollut. Bull. 14: 81–84.
Chapman, P. M., M. A., Farrell & R. O., Brinkhurst, 1982. Relative tolerances of selected aquatic oligochaetes to individual pollutants and environmental factors. Aquat. Toxicol. 2: 47–67.
Chutter, F. M., 1972. An empirical biotic index of the quality of water in South African streams and rivers. Water Res. 6: 19–30.
Cook, S. E. K., 1976. Quest for an index of community structure sensitive to water pollution. Environ. Pollut. 11: 269–288.
Corkum, L. D. & D. C., Currie, 1987. Distributional patterns of immature Simuliidae (Diptera) in northwestern North America. Freshw. Biol. 17: 201–221.
Cummins, K. W., 1988. The study of stream ecosystems: A functional view. In: L. R., Pomeroy & J. J., Alberts (eds),Concepts of Ecosystem Ecology. pp. 247–262. Springer-Verlag, New York.
Dance, K. W. & H. B. N., Hynes, 1980. Some effects of agricultural land use on stream insect communities. Environ. Pollut. 22: 19–28.
De, Pauw, N. & G., Vanhooren, 1983. Method for biological quality assessment of watercourses in Belgium. Hydrobiologia 100: 153–168.
Furse, M. T., D., Moss, J. F., Wright & P. D., Armitage, 1984. The influence of seasonal and taxonomic factors on the ordination and classification of running-water sites in Great Britain and on the prediction of their macroinvertebrate communities. Freshw. Biol. 14: 257–280.
Giesy, J. P. & R. A., Hoke, 1989. Freshwater sediment toxicity bioassessment: rationale for species selection and test design. J. Great Lakes Res. 15: 539–569.
Green, R. H., 1979.Sampling Design and Statistical Methods for Environmental Biologists. John Wiley and Sons Ltd., New York, 257 pp.
Hawkins, C. P. & J. R., Sedell, 1981. Longitudinal and seasonal changes in functional organization of macroinvertebrate communities in four Oregon streams. Ecology 62: 387–397.
Higler, L. W. G. & H. H., Tolkamp, 1983. Hydropsychidae as bio-indicators. Environ. Monit. Assess. 3: 331–341.
Hilsenhoff, W. L., 1987. An improved biotic index of organic stream pollution. Great Lakes Entomol. 20: 31–39.
Hilsenhoff, W. L., 1988. Rapid field assessment of organic pollution with a family-level biotic index. J. North Amer. Bentholog. Soc. 7: 65–68.
Hruby, T., 1987. Using similarity measures in benthic impact assessments. Environ. Monit. Assess. 8: 163–180.
Hughes, R. M. & D. P., Larsen, 1988. Ecoregions: An approach to surface water protection. J. Water Pollut. Control Fed. 60: 486–493.
Hynes, H.B. N., 1960.The Biology of Polluted Waters. Liverpool Univ. Press, Liverpool, 202 pp.
IJC (International Joint Commission), 1987. Guidance on Characterization of Toxic Substances Problems in Areas of Concern in the Great Lakes Basin. Rep. Surveillance Work Group, Windsor, Ontario, 177 pp.
IJC, 1988. Procedures for the Assessment of Contaminated Sediment Problems in the Great Lakes. Rep. Sediment Sub-Committee, Windsor, Ontario, 140 pp.
Johnson, R. K. & T., Wiederholm, 1989. Classification and ordination of profundal macroinvertebrate communities in nutrient poor, oligo-mesohumic lakes in relation to environmental data. Freshw. Biol. 21: 375–386.
Karr, J. R., 1991. Biological integrity: A long-neglected aspect of water resource management. Ecolog. Applic. 1: 66–84.
King, J. M., 1981. The distribution of invertebrate communities in a small South African river. Hydrobiologia 83: 43–65.
Kolkwitz, R. & M., Marsson, 1909. Ökologie der tierische Saprobien. Beiträge zur Lehre von der biologische Gewässerbeurteilung. Internat. Rev. Hydrobiol. 2: 126–152.
Lang, C. & B., Lang-Dobler, 1979. The chemical environment of tubificid and lumbriculid worms according to the pollution level of the sediment. Hydrobiologia 65: 273–282.
Lauritsen, D. D., S. C., Mozley & D. S., White, 1985. Distribution of oligochaetes in Lake Michigan and comments on their use as indices of pollution. J. Great Lakes Res. 11: 67–76.
Long, E. R. & P. M., Chapman, 1985. A sediment quality triad: Measures of sediment contamination, toxicity and infaunal community composition in Puget Sound. Mar. Pollut. Bull. 16: 405–415.
Mason, W. T.Jr, P. A., Lewis & C. I., Weber, 1985. An evaluation of benthic macroinvertebrate biomass methodology. Environ. Monit. Assess. 5: 399–422.
Metcalfe, J. L., 1989. Biological water quality assessment of running waters based on macroinvertebrate communities: History and present status in Europe. Environ. Pollut. 60: 101–139.
Milbrink, G., 1983. Characteristic deformities in tubificid oligochaetes inhabiting polluted bays of Lake Vanern, southern Sweden. Hydrobiologia 106: 169–184.
Monk, D. C., 1983. The uses and abuses of ecotoxicology. Mar. Pollut. Bull. 14: 284–288.
Moss, D., M. T., Furse, J. F., Wright & P. D., Armitage, 1987. The prediction of the macro-invertebrate fauna of unpolluted running-water sites in Great Britain using environmental data. Freshw. Biol. 17: 41–52.
Naylor, C., L., Maltby & P., Calow, 1989. Scope for growth inGammarus pulex, a freshwater benthic detritivore. Hydrobiologia 188/189: 517–523.
Ohio EPA (Ohio Environmental Protection Agency), 1987. Biological criteria for the protection of aquatic life: Volume II. Users manual for biological field assessment of Ohio surface waters. Division of Water Quality Monitoring and Assessment, Surface Water Section, Columbus, Ohio, 44 pp.
Olive, J. H., J. L., Jackson, J., Bass, L., Holland & T., Savisky, 1988. Benthic macroinvertebrates as indexes of water quality in the upper Cuyahoga River. Ohio J. Sci. 88: 91–98.
Ormerod, S. J. & R. W., Edwards, 1987. The ordination and classification of macroinvertebrate assemblages in the catchment of the River Wye in relation to environmental factors. Freshw. Biol. 17: 533–546.
Patrick, R., 1949. A proposed biological measure of stream conditions, based on a survey of the Conestoga Basin, Lancaster County, Pennsylvania. Proc. Acad. Natur. Sci. Philadelphia 101: 277–342.
Patrick, R., 1951. A proposed biological measure of stream conditions. Verh. Internat. Verein. Limnol. 11: 299–307.
Perkins, J. L., 1983. Bioassay evaluation of diversity and community comparison indexes. J. Water Pollut. Control Fed 55: 522–530.
Persoone, G. & N.De, Pauw, 1979. Systems of biological indicators for water quality assessment. In: O., Ravera (ed.),Biological Aspects of Freshwater Pollution. pp. 39–75. Pergamon Press, Oxford.
Pinder, L. C. V., M., Ladle, T., Gledhill, J. A. B., Bass & A. M., Matthews, 1987. Biological surveillance of water quality — 1. A comparison of macro-invertebrate surveillance methods in relation to assessment of water quality, in a chalk stream. Arch. Hydrobiol. 109: 207–226.
Rabeni, C. F., S. P., Davies & K. E., Gibbs, 1985. Benthic invertebrate response to pollution abatement: Structural changes and functional implications. Water Resources Bull. 21: 489–497.
Rae, J. G., 1989. Chironomid midges as indicators of organic pollution in the Scioto River Basin, Ohio. Ohio J. Sci. 89: 5–9.
Reynoldson, T. B., 1984. The utility of benthic invertebrates in water quanlity monitoring. Water Qual. Bull. 10: 21–28.
Reynoldson, T. B. & M. A., Zarull. 1989. The biological assessment of contaminated sediments—the Detroit River example. Hydrobiologia 188/189: 463–476.
Rosenberg, D. M., H. V., Danks & D. M., Lehmkuhl, 1986. Importance of insects in environmental impact assessment. Environ. Managem. 10: 773–783.
Saether, O. A., 1979. Chironomid communities as water quality indicators. Holarct. Ecol. 2: 65–74.
Sheldon, A. L., 1984. Cost and precision in a stream sampling program. Hydrobiologia 3: 147–152.
Slooff, W., 1983. Benthic macroinvertebrates and water quality assessment: Some toxicological considerations. Aquat. Toxicol. 4: 73–82.
U.S. EPA (United States Environmental Protection Agency), 1990. Biological Criteria: National Program Guidance for Surface Waters. EPA-440/5-90-004, 57 pp.
Vannote, R. L., G. W., Minshall, K. W., Cummins, J. R., Sedell & C. E., Cushing, 1980. The River Continuum Concept. Can. J. Fish. Aquat. Sci. 37: 130–137.
Warren, C. E., 1971.Biology and Water Pollution Control. W.B. Saunders Co., Philadelphia, 434 pp.
Warwick, W. F., 1980. Palaeolimnology of the Bay of Quinte, Lake Ontario: 2800 years of cultural influence. Can. Bull. Fish. Aquat. Sci. 206.
Warwick, W. F., 1985. Morphological abnormalities in Chironomidae (Diptera) Iarvae as measures of toxic stress in freshwater ecosystems: indexing antennal deformities inChironomus Meigen. Can. J. Fish. Aquat. Sci. 42: 1881–1914.
Warwick, W. F., 1990. Morphological deformities in Chironomidae (Diptera) larvae from the Lac St Louis and Laprairie basins of the St. Lawrence River. J. Great Lakes Res. 16: 185–208.
Washington, H. G., 1984. Diversity, biotic and similarity indices. A review with special relevance to aquatic ecosystems. Water Res. 18: 653–694.
Wilhm, J. L. & T. C., Dorris, 1968. Biological parameters for water quality criteria. BioScience 18: 477–481.
Winner, R. W., M. W., Boesel & M. P., Farrell, 1980. Insect community structure as an index of heavy-metal pollution in lotic ecosystems. Can. J. Fish. Aquat. Sci. 37: 647–655.
Wright, J. F., D., Moss, P. D., Armitage & M. T., Furse, 1984. A preliminary classification of running-water sites in Great Britain based on macro-invertebrate species and the prediction of community type using environmental data. Freshw. Biol. 14: 221–256.
Wright, J. F., P. D., Armitage, M. T., Furse & D., Moss, 1988. A new approach to the biological surveillance of river quality using macroinvertebrates. Verh. Internat. Verein. Limnol. 23: 1548–1552.
Wright, J. F., P. D., Armitage, M. T., Furse & D., Moss, 1989. Prediction of invertebrate communities using stream measurements. Regulated Rivers: Research & Management 4: 147–155.
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
Reynoldson, T.B., Metcalfe-Smith, J.L. An overview of the assessment of aquatic ecosystem health using benthic invertebrates. J Aquat Ecosyst Stress Recov 1, 295–308 (1992). https://doi.org/10.1007/BF00044171
Issue Date:
DOI: https://doi.org/10.1007/BF00044171