Abstract
The use of feathers is a non-invasive and repeatable method for biomonitoring trace element levels in birds and their ecosystems. Trace element levels were examined in different parts of growing flight feathers from young common terns (Sterna hirundo) to determine distribution of heavy metals and selenium, potential bias from using partially grown feathers, and whether additional heavy metals and selenium are excreted in feather sheaths that are sloughed before feathers are usually sampled. Lead and mercury levels were significantly higher in the distal fully formed portion of the growing feather (with no residual blood supply) compared to the proximal, growing portion of the feather with a residual blood supply, but no significant differences were evident for cadmium and selenium. These results suggest that using partially grown feathers underestimates the amount of lead and mercury in fully formed feathers and that higher levels of lead and mercury are sequestered in feathers than are present in the blood at any one time. Significantly higher concentrations of lead and cadmium, and significantly lower levels of mercury were in the sheath compared to the whole feather blade. These data suggest that birds excrete more lead and cadmium during molt than previously thought.
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References
Applequist H, Asbirk S, Draback L (1984) Mercury stability in bird feathers. Mar Pollut Bull 15:22
Braune BM (1987) Comparison of total mercury levels in relation to diet and molt for nine species of marine birds. Arch Environ Contam Toxicol 16:217–224
Braune BM, Gaskin DE (1987) Mercury levels in Bonaparte's gulls Larus philadelphia during autumn molt in the Quoddy Region, New Brunswick, Canada. Arch Environ Contam Toxicol 16:539–549
Buhler U, Norheim G (1981) The mercury content in feathers of the sparrow hawk Accipiter nisus in Norway. Fauna Norv Ser C. Cinclus 5:43–46
Burger J, Gochfeld M (1991a) Cadmium and lead in common terns (Aves: Sterna hirundo) relationship between levels in parents and eggs. Environ Monitor and Assess 16:253–258
—, — (1991b) Lead, mercury, and cadmium in feathers of tropical terns in Puerto Rico and Australia. Arch Environ Contam Toxicol 21:311–315
Fimreite N, Brun E, Froslie A, Fredericksen P, Gundersen N (1974) Mercury in eggs of Norwegian seabirds. Astarte 1:71–75
Furness RW, Muirhead SJ, Woodburn M (1986) Using bird feathers to measure mercury in the environment: relationship between mercury content and moult. Mar Pollut Bull 17:27–30
Furness RW, Lewis SA (1990) Mercury levels in plumage of red-billed gulls Larus novaehollandiae scopulinus of known sex and age. Environ Pollut 63:33–39
Gochfeld M (1980a) Mercury levels in some seabirds of the Humboldt Current, Peru. Environ Pollut (Series A) 22:197–205
— (1980b) Tissue distribution of mercury in normal and abnormal young common terns. Mar Pollut Bull 11:362–366
Gochfeld M, Saliva J, Lesser F, Shukla T, Bertraud D, Burger J (1991) Effects of color and cadmium and lead levels in avian contour feathers. Arch Environ Contamin Toxicol 20:523–526
Goede AA (1985) Mercury, selenium, arsenic and zinc in waders from the Dutch Wadden Sea. Environ Pollut (Ser. A) 37:287–309
Grue CE, Hoffman DJ, Beyer WN, Franson LP (1986) Lead concentrations and reproductive success in European starlings Sturnus vulgaris nesting within highway roadside verges. Environ Pollut (Ser. A) 42:157–182
Hoffman RD, Curnow RD (1979) Mercury in herons, egrets, and their foods. J Wildl Manage 43:85–93
Mayack LA, Bush PB, Fletcher OJ, Page PK, Fendley TT (1981) Tissue residues of dietary cadmium in wood ducks. Arch Environ Contam Toxicol 10:637–645
Osborn D (1979) Seasonal changes in the fat, protein and metal content of the liver of the starling Sturnus vulgaris. Environ Pollut 19: 145–155
Solonen T, Lodenius M (1984) Mercury in Finnish sparrow hawks Accipiter nisus. Ornis Fenn 61:58–63
—, — (1990) Feathers of birds of prey as indicators of mercury contamination in southern Finland. Holartic Ecology 13:299–237
Tejning S (1967) Biological effects of methylmercury dicyandiamide-treated grain in the domestic fowl Gallus gallus. Oikos Suppl 8:1–116
USEPA (1981) Interim methods for the sampling and analyses of priority pollutants in sediments and fish tissues. US Environmental Protection Agency, Cincinnati, OH
Walsh PM (1988) Geographical variation in mercury levels in North Atlantic Gannets Sula bassana, presented at 3rd Int. Conf. Seabirds Group. Cambridge, February 12–14, 1988
— (1990) The use of seabirds as monitors of heavy metals in the marine environment. In: Furness RW, Rainbow PS (eds) Heavy metals in the marine environment. CRC Press, Boca Raton, FL
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Burger, J., Gochfeld, M. Trace element distribution in growing feathers: Additional excretion in feather sheaths. Arch. Environ. Contam. Toxicol. 23, 105–108 (1992). https://doi.org/10.1007/BF00226002
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DOI: https://doi.org/10.1007/BF00226002