Abstract
In forest areas receiving aerial application of pesticides, small bodies of water, which are often difficult to see from low-flying spray planes, are at risk of receiving high concentrations of contaminants. To determine the sensitivity of bog pond invertebrate communities, formulated fenitrothion was applied at ground level with a mist blower to four acidic bog ponds near Lake George, New Brunswick, Canada. Fenitrothion fate and persistence, insect emergence, gyrinid populations, and the invertebrate community inhabiting the floating sphagnum fringe of the ponds were sampled before and after treatment.
The invertebrate community was sensitive to formulated fenitrothion. Concentrations of fenitrothion in bog pond water were in ranges that would be expected after a direct aerial application, with no buffer zone, of 2×210 g active-ingredient/ha, the operational emission rate used for spruce budworm. Insect emergence was reduced compared to control ponds for 6–12 weeks following fenitrothion treatment. The population densities of Chironomidae and Ceratopogonidae were reduced by more than 50% for 1 month after treatment. The densities of most other benthic insect taxa were also reduced. Some reductions in density lasted over winter into the next year. This contrasted with the usual small and transitory effects of fenitrothion on aquatic invertebrate communities in streams or large lakes.
Insecticide-induced suppression of aquatic insects and adult insect emergence in the small bog ponds allowed Hydrachnellae, Oligochaeta, and Nematoda to dominate the aquatic invertebrate community. Export of energy and nutrients to the terrestrial system through insect emergence was thus reduced and cycling or retention within the aquatic system increased. Sustained suppression of insect emergence could result in nutrient accumulation in the ponds. Substantially reduced insect emergence would be expected to have effects on dependent predators in the bog ecosystem.
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References
Baarchers WH, Elvish J, Ryan SP (1983) Adsorption of fenitrothion and 3-methyl-4-nitrophenol on soils and sediment. Bull Environ Contam Toxicol 30:621–627
Batt BDJ, Anderson MG, Anderson CD, Caswell FD (1989) The use of prairie potholes by North American ducks. Pages 204–227, In: VanderValk A (ed) Northern prairie wetlands. Iowa State University Press, Ames, IA, pp 204–227
Bliss LC (1975) Devon Island, Canada. In: Rosswall T, Heal OW (eds) Structure and function of tundra ecosystems. Ecol Bull, Stockholm, Vol 20, pp 17–60
Burnett JA (1992) The forty-year war. Nature Canada, Fall 1992:29–35
Coulson JC, Whittaker JB (1978) Ecology of Moorland Animals. In: Heal OW, Perkins DF (eds) Production ecology of British moors and montane grasslands. Springer-Verlag, NY, pp 52–93
Eidt DC (1975) The effect of fenitrothion from large-scale forest spraying on benthos in New Brunswick headwater streams. Can Entomol 107:743–760
— (1981) Recovery of aquatic arthropod populations in a woodland stream after depletion by fenitrothion treatment. Can Entomol 113:303–313
Eidt DC, Sosiak AJ, Mallet VN (1984) Partitioning and short-term persistence of fenitrothion in New Brunswick (Canada) headwater streams. Arch Environ Contam Toxicol 13:43–52
Elliott JM (1977) Some methods for the statistical analysis of samples of benthic invertebrates. Freshwater Biol Assoc Sci Publ No. 25
Ernst W, Julien G, Hennigar P (1991) Contamination of ponds by fenitrothion during forest spraying. Bull Environ Contam Toxicol 46:815–821
Fairchild WL (1990) Perturbation of the aquatic invertebrate community of acidic bog ponds by the insecticide fenitrothion. PhD Thesis, University of New Brunswick, Fredericton, New Brunswick, Canada
Fairchild WL, Ernst WR, Mallet VN (1989) Fenitrothion effects on aquatic organisms. In: Ernst WR, Pearce PA, Pollock TL (eds) Environmental effects of fentrothion use in forestry. Environment Canada, Conservation and Protection, Atlantic Region, Dartmouth, NS, Canada pp 109–166
Fairchild WL, O'Neill MCA, Rosenberg DM (1987) Quantitative evaluation of the behavioral extraction of aquatic invertebrates from samples of sphagnum moss. J North Am Benthol Soc 6:281–287
Fairchild WL, Wiggins GB (1989) Immature stages and biology of the North American caddisfly genus Phanocelia Banks (Trichoptera: Limnephilidae). Can Entomol 121:515–519
Gaboury G, Marotte P-M, Morin R, Pelletier M (1981) Compilation bibliographique concernant la toxicité et les effets environnementaux du fénitrothion, de l'aminocarb et du Bacillus thuringiensis Berliner. Rapport Interne EP-81–02. Ministère de l'Énergie et des Ressources, Québec
Gibbs KE, Mingo TM, Courtemanch DL (1984) Persistence of carbaryl (Sevin®-4-oil) in woodland ponds and its effects on pond macroinvertebrates following forest spraying. Can Entomol 116:203–213
Green RH (1979) Sampling design and statistical methods for environmental biologists. John Wiley and Sons, NY
Grue CE, Tome MW, Samson GA, Borthwick SM, DeWeese LR (1988) Aerial application of insecticides and declines in waterfowl production within the prairie-pothole region. Presentation to the 9th Annual SETAC meeting November 13–17, 1988. Abstract: 159
Haché P, Marquette R, Volpe G, Mallet VN (1981) Fast cleanup of difficult substrates for determination of fenitrothion and some derivatives. J Assoc Offic Anal Chem 64:1470–1473
Hasegawa J, Yasuno M, Saito K, Nakamura Y, Hatakeyama S, Sato OH (1982) Impact of temephos and fenitrothion on aquatic invertebrates in a stream of Mount Tsukuba, Japan. Jpn J Sanit Zool 33:363–368
Hatakeyama S, Shiraishi H, Kobayashi N (1990) Effects of aerial spraying of insecticides on nontarget macrobenthos in a mountain stream. Ecotoxicol Environ Saf 19:254–270
Hiramatsu R, Furutani F, Nagira M, Oka H, Tasaka M (1990) Environmental behaviour of fenitrothion aerially sprayed over forests for control of pine sawyer beetles (Monochamus alternatus). J Pestic Sci 15:23–30
Heal OW, Jones HE, Whittaker JB (1975) Moor House, UK. In: Rosswall T, Heal OW (eds) Structure and function of tundra ecosystems. Ecol Bull, Stockholm, vol 20, pp 295–320
Heal OW, Perkins DF (eds) (1978) Production ecology of British moors and montane grasslands. Springer-Verlag, NY
Hurlbert SH (1975) Secondary effects of pesticides on aquatic ecosystems. Residue Rev 57:81–148
— (1984) Pseudoreplication and the design of ecological field experiments. Ecol Monogr 54:187–211
Hynes HB (1960) The biology of polluted waters. Liverpool University Press, Liverpool
— (1970) The ecology of running waters. University of Toronto Press, Toronto, Canada
Jackson JK, Fisher SG (1986) Secondary production, emergence, and export of aquatic insects of a Sonoran desert stream. Ecology 67:629–638
Jackson JK, Resh VH (1989) Distribution and abundance of adult aquatic insects in the forest adjacent to a Northern California Stream. Environ Entomol 18:278–283
Kingsbury PD (1975) Effects of aerial forest spraying on aquatic fauna. In: Prebble ML (ed) Aerial control of forest insects in Canada. Environment Canada, Ottawa, Canada, pp 280–292
--(1977) Fenitrothion in a lake ecosystem. Can. For. Serv. Chem. Control Res. Inst. Rep. CC-X-146
— (1984) Environmental impact assessment of insecticides used in Canadian forests. In: Garner WY, Harvey J Jr. (eds) Chemical and biological controls in forestry, ACS Symp Ser 238. Am Chem Soc, Washington, DC, pp 365–376
Kondratieff PF, Matthews RA, AL Buikema Jr (1984) A stressed stream ecosystem: macroinvertebrate community integrity and microbial trophic response. Hydrobiologia 111:81–91
Larson DJ, House NL (1990) Insect communities of Newfoundland bog pools with emphasis on the Odonata. Can Entomol 122:469–501
Likens GE, Bormann FH (1974) Linkages between terrestrial and aquatic ecosystems. Bioscience 24:447–456
Likens GE, Loucks OL (1978) Analysis of five North American lake ecosystems III. Sources, loading and fate of nitrogen and phosphorus. Int Assoc Theor Appl Limnol Proc 20:568–573
Maguire RJ (1991) Kinetics of pesticide volatilization from the surface of water. J Agric Food Chem 39:1674–1678
Maguire RJ, Hale EJ (1980) Fenitrothion sprayed on a pond: kinetics of its distribution and transformation in water and sediment. J Agric Food Chem 28:372–378
Malis GP, Muir DCG (1984) Fate of fenitrothion in shaded and unshaded ponds. In: Garner WY, Harvey J Jr (eds) Chemical and biological controls in forestry, ACS Symp Ser 238. Am Chem Soc, Washington, DC, pp 277–296
Mason CF, MacDonald SM (1982) The input of terrestrial invertebrates from tree canopies to a stream. Freshwater Biol 12:305–311
Merritt RW, Cummins KW, (eds) (1984) Aquatic insects of North America (2nd ed). Kendall/Hunt Publ Co, Dubuque, IA
Miyamoto J (1977) Degradation of fenitrothion in terrestrial and aquatic environments including photolytic and microbial reactions. In: Roberts JR, Greenhalgh R, Marshall WK (eds) Fenitrothion: The long-term effects of its use in forest ecosystems, NRCC No. 16073. NRCC, Ottawa, Canada, pp 105–134
Moore JJ, Dowding P, Healy B (1975) Glenamoy, Ireland. In: Rosswall T, Heal OW (eds) Structure and function of tundra ecosystems. Ecol Bull, Stockholm, vol 20, pp 321–343
Morrison BRS, Wells DE (1981) The fate of fenitrothion in a stream environment and its effect on the fauna following aerial spraying of a Scottish forest. Sci Total Environ 19:233–252
Murkin HR, Batt BDJ (1987) The interactions of vertebrates and invertebrates in peatlands and marshes. Mem Entomol Soc Can 140:15–30
National Research Council of Canada (1975) Fenitrothion: The effects of its use on environmental quality and its chemistry, NRCC No. 14104. NRCC, Ottawa, Canada
— (1977) Fenitrothion: The long-term effects of its use in forest ecosystems, NRCC No. 16073. NRCC, Ottawa, Canada
— (1982) Aminocarb: The effects of its use on the forest and the human environment. NRCC No. 18979. NRCC, Ottawa, Canada
Oliver DR (1971) Life history of the Chironomidae. Annu Rev Entomol 16:211–230
Orlob GT (1984) Mathematical models of lakes and reservoirs. In: Taub FB (ed) Lakes and reservoirs, Ecosystems of the world, No. 23. Elsevier, Amsterdam, pp 43–62
Ostbye E (ed) (1975) Hardangervidda, Norway. In: Rosswall T, Heal OW (eds) Structure and function of tundra ecosystems. Ecol Bull, Stockholm, vol 20, pp 225–264
Pennak RW (1978) Fresh-water invertebrates of the United States. John Wiley and Sons, NY
Poirier DG (1986) The toxicity of four insecticides used in forest pest management in Canada to selected aquatic invertebrates. M.Sc. Thesis, Univ. of Guelph, Guelph, Ontario, Canada
Poirier DG, Surgeoner GA (1986) Evaluation of the toxicity of spruce budworm insecticides to aquatic invertebrates. Can Tech Rep Fish Aquat Sci 1462:99–120
Proctor H, Pritchard G (1989) Neglected predators: water mites (Acari: Parasitengona: Hydrachnellae) in freshwater communities. J North Am Benthol Soc 8:100–111
Rawes M, Heal OW (1978) The blanket bog as part of a Pennine moorland. In: Heal OW, Perkins DF (eds) Production ecology of British moors and montane grasslands. Springer-Verlag, NY, pp 224–243
Rogers LE, Hinds WT, Buschbom RL (1976) A general weight vs length relationship for insects. Ann Entomol Soc Am 69:387–389
Rosswall T, Flower-Ellis JGK, Johansson LG, Jonsson S, Ryden BE, Sonesson M (1975) Stordalen (Abisko), Sweden. In: Rosswall T, Heal OW (eds) Structure and function of tundra ecosystem. Ecol Bull Stockholm, vol 20, pp 265–294
Sckizawa J, Eto M, Miyamoto J, Matsuo M (1992) Fenitrothion. Environmental Health Criteria 133, World Health Organization, Geneva
Steele RGD, Torrie RH (1980) Principles and procedures of statistics: a biometrical approach. McGraw-Hill, NY
Sundaram KMS (1974) Persistence studies of insecticides: III. accumulation of fenitrothion and its oxygen analog in foliage, soil and water in Larose Forest. Can For Serv Chem Control Res Inst Inf Rep CC-X-65
— (1990) Foliar and ground deposits of fenitrothion following aerial application over a plantation forest. J Environ Sci Health Part B 25:643–663
Swanson GA, Duebbert HF (1989) Wetland habitats of waterfowl in the prairie pothole region. In: VanderValk A (ed) Northern prairie wetlands. Iowa State University Press, Ames, IA, pp 228–267
Symons PEK (1977) Dispersal and toxicology of the insecticide fenitrothion; predicting hazards of forest spraying. Residue Rev 38: 1–36
Wallace JB (1989) Structure and function of freshwater ecosystems: assessing the potential impact of pesticides. In: Voshell JR Jr. (ed) Using mesocosms to assess the aquatic ecological risk of pesticides: Theory and practice. Misc Publ Entomol Soc Am 75, pp 4–17
Wells ED (1981) Peatlands of eastern Newfoundland: distribution, morphology, vegetation, and nutrient status. Can J Bot 59:1978–1997
Wiggins GB (1977) Larvae of the North American caddisfly genera (Trichoptera). University of Toronto Press, Toronto, Canada
Yasuno M, Okita J, Saito K, Nakamura Y, Hatakeyama S, Kasuga S (1981) Effects of fenitrothion on benthic fauna in small streams of Mount Tsukuba, Japan. Jpn J Ecol 31:237–246
Zoltai SC (1987) Peatlands and marshes in the wetland regions of Canada. Mem Entomol Soc Can 140:5–13
Zoltai SC, Pollett FC (1983) Wetlands in Canada: Their classification, distribution, and use. In: Gore AJP (ed) Mires: Swamp, bog, fen, and moor. Elsevier Scientific Pub Co, Amsterdam, pp 245–268
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Fairchild, W.L., Eidt, D.C. Perturbation of the aquatic invertebrate community of acidic bog ponds by the insecticide fenitrothion. Arch. Environ. Contam. Toxicol. 25, 170–183 (1993). https://doi.org/10.1007/BF00212128
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DOI: https://doi.org/10.1007/BF00212128