Pest Management and Pesticide Impacts

  • David Pimentel
  • David A. Andow


Although pesticides provide benefits in our battle to control pests that destroy more than a third of all food, the use of pesticides also results in significant costs to public health and the environment. As many as 500,000 humans are poisoned annually by pesticides in the world; the United States alone reports about 45,000 human pesticide poisonings.

Pesticides have also caused many detrimental effects on agroecosystems and natural ecosystems. These include: (i) reducing and sometimes eliminating beneficial natural enemies that keep pest populations at low densities; (ii) increasing or decreasing reproduction in various animal populations; (iii) altering decomposition rates of soil organic matter; (iv) developing insecticide resistance in pests, which results in increased pesticide use and additional crop losses; and (v) eliminating honey bee and other bee populations in certain regions thus reducing crop yields and quality. Pesticides also have had major impacts on fish, bird and mammal populations.

Key Words

pesticides environment ecological impacts public health pest management natural biota pest losses 


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  1. Abdallah M. D. (1968) The effect of sublethal dosages of DDT, parathion, and dieldrin on oviposition of the Colorado potato beetle (Leptinotarsa decemlineata) Say. (Coleoptera: Chrysomelidae). Bull. ent. Soc. Egypt econ. Ser. 2, 211–217.Google Scholar
  2. Adkisson P. L. (1971) Objective uses of insecticides in agriculture. In Agricultural Chemicals — Harmony or Discord for Food, People, and the Environment (Edited by Swift J. E.), pp. 43–51. Division of Agricultural Sciences, University of California.Google Scholar
  3. Adkisson P. L. (1972) The integrated control of the insect pests of cotton. Proc. Tall Timbers Conf. Ecol. Anim. Control Habitat Manage. 4, 175–188.Google Scholar
  4. Adkisson P. L. (1977) Alternatives to the unilateral use of insecticides for insect pest control in certain field crops. In Symposium on Ecology and Agricultural Production (Edited by Seatz L. F.), pp. 129–144. University of Tennessee, Knoxville.Google Scholar
  5. Akesson N. B., Yates W. E. and Christensen P. (1972) Aerial dispersion of pesticide chemicals of known emissions, particle size and weather conditions. Abstr. Am. Chem. Soc. Mtgs. Boston.Google Scholar
  6. Akins M. B., Jeffrey L. S., Overton J. R. and Morgan T. H. Jr (1976) Soybean response to preemergence herbicides. Proc. S. Weed Sci. Soc. 29, 50.Google Scholar
  7. Alexander M. (1977) An Introduction to Soil Microbiology. Wiley, New York.Google Scholar
  8. Barrett G. W. (1968) The effects of an acute insecticide stress on a semi-enclosed grassland ecosystem. Ecology 49, 1019–1035.CrossRefGoogle Scholar
  9. Barrett G. W. and Darnell R. M. (1967) Effects of dimethoate on small mammal populations. Am. Midl. Nat. 77, 164–175.CrossRefGoogle Scholar
  10. Benevue A., Hylin J. W., Kawano Y. and Kelley T. W. (1972) Pesticides in water. Organochlorine residues in water, sediment, algae and fish, Hawaii-1970-71. Pestic. Monit. J. 6, 56–64.Google Scholar
  11. van den Bosch R. and Messenger P. S. (1973) Biological Control. Intext Educational Publishers, New York.Google Scholar
  12. Brooker M. P. and Edwards R. W. (1973) Effects of the herbicide paraquat on the ecology of a reservoir. I. Botanical and chemical aspects. Freshwat. Biol. 3, 157–175.CrossRefGoogle Scholar
  13. Brown A. W. A. (1978) Ecology of Pesticides. Wiley, New York.Google Scholar
  14. Clark L. C., Shy C. M., Most B. M., Florin J. W. and Portier K. M. (1977) Cancer mortality and agricultural pesticide use in the southeastern United States. 8th International Scientific Meeting, International Epidemiology Association. San Juan, Puerto Rico.Google Scholar
  15. Cole H., Mackenzie D., Smith C. B. and Bergman E. L. (1968) Influence of various persistent chlorinated insecticides on the macro and micro element constituents of Zea mays and Phaseolus vulgaris growing in soil containing various amounts of these materials. Bull. environ. contam. Toxic. 3, 141–153.CrossRefGoogle Scholar
  16. Croft B. A. (1978) Potentials for research and implementation of integrated pest management on deciduous tree-fruits. In Pest Control Strategies (Edited by Smith E. H. and Pimentel D.), pp. 101–115. Academic Press, New York.CrossRefGoogle Scholar
  17. Croft B. A. and Brown A. W. A. (1975) Responses of arthropod natural enemies to insecticides. A. Rev. Ent. 20, 285–335.CrossRefGoogle Scholar
  18. Debach P. H. (Ed) (1964) Biological Control of Insect Pests and Weeds. Reinhold, New York.Google Scholar
  19. Duggan R. E. and Duggan M. B. (1973) Pesticide residues in food. In Environmental Pollution by Pesticides (Edited by Edwards C. A.), pp. 334–364. Plenum, London.CrossRefGoogle Scholar
  20. Edwards C. A. (1965) Effects of pesticide residues on soil invertebrates and plants. In Ecology and the Industrial Society Symp. Brit. Ecol. Soc. 5 (Edited by Goodman G. T., Edwards R. W. and Lambert J. M.), pp. 239–261. Blackwell, Oxford.Google Scholar
  21. Edwards C. A. (1973a) Environmental Pollution by Pesticides. Plenum, London.CrossRefGoogle Scholar
  22. Edwards C. A. (1973b) Persistent Pesticides in the Environment, 2nd edn. CRC Press, Cleveland.Google Scholar
  23. Edwards C. A. (1980) Interactions between agricultural practice and earthworms. In Soil Biology as Related to Land Use Practices (Edited by Dindal D. L.), pp. 3–11. Office of Pesticide and Toxic Substances, EPA, Washington, D.C.Google Scholar
  24. Edwards C. A. and Lofty J. R. (1977) Biology of Earthworms. Chapman & Hall, London.CrossRefGoogle Scholar
  25. Elliot B. R., Lumb J. M., Reeves T. G. and Telford T. E. (1975) Yield losses in weed-free wheat and barley due to post-emergence herbicides. Weed Res. 15, 107–111.CrossRefGoogle Scholar
  26. EPA (1974) Strategy of the Environmental Protection Agency for controlling the adverse effects of pesticides. Environmental Protection Agency, Office of Pesticide Programs, Office of Water and Hazardous Materials, Washington, D.C.Google Scholar
  27. Henderson J. (1968) Legal aspects of crop spraying. Univ. Ill. Agr. exp. Sta. Circ. 99.Google Scholar
  28. Hueck H. J., Kuener D. J., Denboer P. J. and Jaeger-Draafsel E. (1952) The increase of egg-production of the fruit-tree red spider mite (Metatetranychus ulmi Koch) under influence of DDT. Physiologia comp. oecol. II, 371–377.Google Scholar
  29. Huffaker C. B. (Ed.) (1980) New Technology of Pest Control. Wiley, New York.Google Scholar
  30. Hurlbert S. H. (1975) Secondary effects of pesticides on aquatic ecosystems. Residue Rev. 57, 81–148.PubMedGoogle Scholar
  31. ICAITI (1977) An Environmental and Economic Study of the Consequences of Pesticide Use in Central American Cotton Production. Final Report. Central American Research Institute for Industry, United Nations Environment Programme.Google Scholar
  32. Ignoffo C. M., Hostetter D. L., Garcia C. and Pinnell R. E. (1975) Sensitivity of the entomopathogenic fungus Nomuraea rileyi to chemical pesticides used on soybeans. Environ. Ent. 4, 765–768.Google Scholar
  33. Ishii S. and Hirano C. (1963) Growth responses of larvae of the rice-stem borer to rice plants treated with 2,4-D. Entomologia exp. appl. 6, 257–262.CrossRefGoogle Scholar
  34. Johnson E. K., Young J. H., Molnar D. R. and Morrison R. D. (1976a) Effects of three insect control schemes on populations of cotton insects and spiders, fruit damage, and yield of Westburn 70 cotton. Environ. Ent. 5, 508–510.CrossRefGoogle Scholar
  35. Johnson D. W., Kish L. P. and Allen G. E. (1976b) Field evaluation of selected pesticides on the natural development of the entomopathogen, Nomuraea rileyi, on the velvetbean caterpillar in soybean. Environ. Ent. 5, 964–966.CrossRefGoogle Scholar
  36. Keith J. O., Woods L. A. and Hunt E. C. (1970) Reproductive failure in brown pelicans on the Pacific coast. Trans 35th North American Wildlife and Natural Resources Conference, pp. 56–63.Google Scholar
  37. Keenleyside M. H. A. (1967) Effects of forest spraying with DDT in New Brunswick on food of young Atlantic salmon. J. Fish Res. Bd Can. 24, 807.CrossRefGoogle Scholar
  38. Kinzer E. E., Cowan C. B., Ridgway R. L., Davis J. W., Coppedge J. R. and Jones S. L. (1977) Populations of arthropod predators and Heliothis spp. after applications of aldicarb and monocrotophos to cotton. Environ. Ent. 6, 13–16.CrossRefGoogle Scholar
  39. Koeman J. H., Den Boer W. M. J., Feith A. F., De Iongh H. H., Spliethoff P. C., Na’Isa B. K. and Spielberger V. (1978) Three years’ observation on side effects of helicopter applications of insecticides used to exterminate Glossina species in Nigeria. Environ. Pollut. 15, 31–59.CrossRefGoogle Scholar
  40. Kutz F. W., Strassman S. C. and Yobs A. R. (1977) Survey of pesticide residues and their metabolites in humans. In Pesticide Management and Insecticide Resistance (Edited by Watson D. L. and Brown A. W. A.), pp. 523–539. Academic Press, New York.Google Scholar
  41. Lauer G. J., Pimentel D., Macbeth A., Salwen B. and Seddon J. (1976) Report of the Biological Communities Task Group Report No. 8. Hudson Basin Project, Rockefeller Foundation, New York.Google Scholar
  42. Mahadevan V. and Chandy K. C. (1959) Preliminary studies on the increase in cotton yield due to honeybee pollination. Madras Agr. J. 46, 23–26.Google Scholar
  43. Martin N. A. (1976) Effect of four insecticides on the pasture ecosystem. V. Earthworms (Oligochaeta: Lumbricidae) and arthropods extracted by wet sieving and salt flotation. N.Z. J. Agric. Res. 19, 111–115.CrossRefGoogle Scholar
  44. McGregor S. E. (1976) Insect Pollination of Cultivated Crop Plants. Agricultural Handbook No. 496. USDA, Agr. Res. Serv.Google Scholar
  45. McGregor S. E., Rhyne C., Worley S. Jr and Todd F. E. (1955) The role of honeybees in cotton pollination. Agron. J. 47, 23–25.CrossRefGoogle Scholar
  46. Menhinick E. F. (1962) Comparison of invertebrate populations of soil and litter of mowed grassland in areas treated and untreated with pesticides. Ecology 43, 556–561.CrossRefGoogle Scholar
  47. Metcalf R. L. (1980) Changing role of insecticides in crop protection. A. Rev. Ent. 25, 219–256.CrossRefGoogle Scholar
  48. NAS (1975) Pest Control: An Assessment of Present and Alternative Technologies, Vols I-V. National Academy of Sciences, Washington, D.C.Google Scholar
  49. Newsom L. D. (1962) The boll weevil problem in relation to other cotton insects. Proc. Boll Weevil Research Symp., State College, Miss., pp. 83–94.Google Scholar
  50. Oka I. N. and Pimentel D. (1974) Corn susceptibility to corn leaf aphids and common smut after herbicide treatment. Environ. Ent. 3, 911–915.CrossRefGoogle Scholar
  51. Peakall D. B. (1970) DDT-induced inhibition of avian shell gland carbonic anhydrase: a mechanism for thin eggshells. Science 168, 594–595.CrossRefGoogle Scholar
  52. Pimentel D. (1961a) An ecological approach to the insecticide problem. J. econ. Ent. 54, 108–114.CrossRefGoogle Scholar
  53. Pimentel D. (1961b) Competition and the species-per-genus structure of communities. Ann. ent. Soc. Am. 54, 61–69.CrossRefGoogle Scholar
  54. Pimentel D. (1971) Ecological Effects of Pesticides on Non-target Species. U.S. Govt. Print. Off., Washington, D.C.Google Scholar
  55. Pimentel D. (1976) World food crisis: energy and pests. Bull. ent. Soc. Am. 22, 20–26.Google Scholar
  56. Pimentel D. and Pimentel M. (1979) Food, Energy and Society. Edward Arnold, London.Google Scholar
  57. Pimentel D. and Edwards C. A. (1982) Pesticides and ecosystems. BioScience 32, 595–600.CrossRefGoogle Scholar
  58. Pimentel D., Dritschilo W., Krummel J. and Kutzman J. (1975) Energy and land constraints in food production. Science 190, 254–261.CrossRefGoogle Scholar
  59. Pimentel D., Shoemaker C., Ladue E. L., Rovinsky R. B. and Russell N. P. (1977) Alternatives for Reducing Insecticides on Cotton and Corn: Economic and Environmental Impact. Report on Grant No. R802518-02. Office of Research and Development, Environmental Protection Agency.Google Scholar
  60. Pimentel D., Krummel J., Gallahan D., Hough J., Merrill A., Schreiner I., Vittum P., Koziol F., Back E., Yen D. and Fiance S. (1978). Benefits and costs of pesticide use. BioScience 28, 772, 778–784.Google Scholar
  61. Pimentel D., Andow D., Dyson-Hudson R., Gallahan D., Jacobson S., Irish M., Kroop S., Moss A., Schreiner I., Shepard M., Thompson T. and Vinzant B. (1980a) Environmental and social costs of pesticides: a preliminary assessment. Oikos 34, 127–140.CrossRefGoogle Scholar
  62. Pimentel D., Andow D., Dyson-Hudson R., Gallahan D., Jacobson S., Irish M., Kroop S., Moss A., Schreiner I., Shepard M., Thompson T. and Vinzant B. (1980b) Pesticides: environmental and social costs. In Pest Control: Cultural and Environmental Aspects (Edited by Pimentel D. and Perkins J. H.), pp. 99–158. Westview Press, Boulder, Co.Google Scholar
  63. Plapp F. W. and Vinson S. B. (1977) Comparative toxicities of some insecticides to the tobacco budworm and its ichneumonid parasite, Campoletis sonorensis. Environ. Ent. 6, 381–384.CrossRefGoogle Scholar
  64. Potts G. R. and Vickerman G. P. (1974) Studies on the cereal ecosystem. Adv. ecol. Res. 8, 107–197.CrossRefGoogle Scholar
  65. Reinert R. E. (1967) The accumulation of dieldrin in an alga (Scenedesmus obliquus), Daphnia (Daphnia magna), and the guppy (Lebistes reticulatus) food chain. Ph.D. dissertation. Univ. Michigan, Ann Arbor.Google Scholar
  66. Reinert R. E. (1972) Accumulation of dieldrin in an alga (Scenedesmus obliquus), Daphnia magna, and the guppy (Poecilia reticulata). (J. Fish Res. Bd Can. 29, 1413–1418.CrossRefGoogle Scholar
  67. Ridgway R. L., Lingren P. D., Cowan C. B. and Davis J. W. (1967) Populations of arthropod predators and Heliothis spp. after applications of systemic insecticides to cotton. J. econ. Ent. 60, 1012–1096.Google Scholar
  68. Rosene W. and Lay D. W. (1963) Disappearance and visibility of quail remains. J. Wildl. Mgmt 27, 139–142.CrossRefGoogle Scholar
  69. von Rumker R. and Horay F. (1974) Farmers’ Pesticide Use Decisions and Attitudes on Alternative Crop Protection Methods. U.S. Environmental Protection Agency, Washington, D.C.Google Scholar
  70. van Steenwyk R. A., Toscano N. C., Ballmer G. R., Kido K. and Reynolds H. T. (1975) Increases of Heliothis spp. in cotton under various insecticide treatment regimes. Environ. Ent. 4, 993–996.CrossRefGoogle Scholar
  71. Thompson A. R. and Edwards C. A. (1974) Effects of pesticides on nontarget invertebrates in freshwater and soil. In Pesticides in Soil and Water (Edited by Guenzi W. D.), pp. 341–386. Soil Sci. Soc. Am., Madison.Google Scholar
  72. USDA (1975) Farmers’ use of pesticides in 1971 — extent of crop use. Econ. Res. Serv., Agr. Econ. Rep. No. 268.Google Scholar
  73. USDA (1976) The Pesticide Review 1975. U.S. Dept. Agr., Agr. Stab. Conserv. Serv.Google Scholar
  74. Ware G. W., Cahill W. P., Gerhardt P. D. and Witt J. M. (1970) Pesticides drift IV. On-target deposits from aerial application of insecticides. J. econ. Ent. 63, 1982–1983.CrossRefGoogle Scholar
  75. Weir D. and Schapiro M. (1981) Circle of Poison. Institute pf Food and Development Policy, San Francisco.Google Scholar
  76. WHO (1981) Pesticide deaths: what’s the toll? Ecoforum 6, 10.Google Scholar

Copyright information

© ICIPE 1984

Authors and Affiliations

  • David Pimentel
    • 1
  • David A. Andow
    • 1
  1. 1.Department of Entomology and Section of Ecology and SystematicsCornell UniversityIthacaUSA

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