Understanding sources of methylmercury in songbirds with stable mercury isotopes: Challenges and future directions

Mercury (Hg) stable isotope analysis is an emerging technique that has contributed to a better understanding of many aspects of the biogeochemical cycling of Hg in the environment. However, no study has yet evaluated its usefulness in elucidating the sources of methylmercury (MeHg) in songbird speci...

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Published in:Environmental Toxicology and Chemistry
Main Authors: Tsui, Martin Tsz‐ki, Adams, Evan M., Jackson, Allyson K., Evers, David C., Blum, Joel D, Balogh, Steven J.
Format: Article in Journal/Newspaper
Language:unknown
Published: Maine Agricultural and Forest Experiment Station 2018
Subjects:
Online Access:http://hdl.handle.net/2027.42/141144
https://doi.org/10.1002/etc.3941
id ftumdeepblue:oai:deepblue.lib.umich.edu:2027.42/141144
record_format openpolar
institution Open Polar
collection University of Michigan: Deep Blue
op_collection_id ftumdeepblue
language unknown
topic Trophic transfer
Songbird
Wetland
Methylation
Isotopic fractionation
Natural Resources and Environment
Biological Chemistry
Science
spellingShingle Trophic transfer
Songbird
Wetland
Methylation
Isotopic fractionation
Natural Resources and Environment
Biological Chemistry
Science
Tsui, Martin Tsz‐ki
Adams, Evan M.
Jackson, Allyson K.
Evers, David C.
Blum, Joel D
Balogh, Steven J.
Understanding sources of methylmercury in songbirds with stable mercury isotopes: Challenges and future directions
topic_facet Trophic transfer
Songbird
Wetland
Methylation
Isotopic fractionation
Natural Resources and Environment
Biological Chemistry
Science
description Mercury (Hg) stable isotope analysis is an emerging technique that has contributed to a better understanding of many aspects of the biogeochemical cycling of Hg in the environment. However, no study has yet evaluated its usefulness in elucidating the sources of methylmercury (MeHg) in songbird species, a common organism for biomonitoring of Hg in forested ecosystems. In the present pilot study, we examined stable mercury isotope ratios in blood of 4 species of songbirds and the invertebrates they are likely foraging on in multiple habitats in a small watershed of mixed forest and wetlands in Acadia National Park in Maine (USA). We found distinct isotopic signatures of MeHg in invertebrates (both massâ dependent fractionation [as δ202Hg] and massâ independent fractionation [as Î 199Hg]) among 3 interconnected aquatic habitats. It appears that the Hg isotopic compositions in bird blood cannot be fully accounted for by the isotopic compositions of MeHg in lower trophic levels in each of the habitats examined. Furthermore, the bird blood isotope results cannot be simply explained by an isotopic offset as a result of metabolic fractionation of δ202Hg (e.g., internal demethylation). Our results suggest that many of the birds sampled obtain MeHg from sources outside the habitat they were captured in. Our findings also indicate that massâ independent fractionation is a more reliable and conservative tracer than massâ dependent fractionation for identifying sources of MeHg in bird blood. The results demonstrate the feasibility of Hg isotope studies of songbirds but suggest that larger numbers of samples and an expanded geographic area of study may be required for conclusive interpretation. Environ Toxicol Chem 2018;37:166â 174. © 2017 SETAC Peer Reviewed https://deepblue.lib.umich.edu/bitstream/2027.42/141144/1/etc3941.pdf https://deepblue.lib.umich.edu/bitstream/2027.42/141144/2/etc3941_am.pdf
format Article in Journal/Newspaper
author Tsui, Martin Tsz‐ki
Adams, Evan M.
Jackson, Allyson K.
Evers, David C.
Blum, Joel D
Balogh, Steven J.
author_facet Tsui, Martin Tsz‐ki
Adams, Evan M.
Jackson, Allyson K.
Evers, David C.
Blum, Joel D
Balogh, Steven J.
author_sort Tsui, Martin Tsz‐ki
title Understanding sources of methylmercury in songbirds with stable mercury isotopes: Challenges and future directions
title_short Understanding sources of methylmercury in songbirds with stable mercury isotopes: Challenges and future directions
title_full Understanding sources of methylmercury in songbirds with stable mercury isotopes: Challenges and future directions
title_fullStr Understanding sources of methylmercury in songbirds with stable mercury isotopes: Challenges and future directions
title_full_unstemmed Understanding sources of methylmercury in songbirds with stable mercury isotopes: Challenges and future directions
title_sort understanding sources of methylmercury in songbirds with stable mercury isotopes: challenges and future directions
publisher Maine Agricultural and Forest Experiment Station
publishDate 2018
url http://hdl.handle.net/2027.42/141144
https://doi.org/10.1002/etc.3941
genre Arctic
genre_facet Arctic
op_relation Tsui, Martin Tsz‐ki
Adams, Evan M.; Jackson, Allyson K.; Evers, David C.; Blum, Joel D.; Balogh, Steven J. (2018). "Understanding sources of methylmercury in songbirds with stable mercury isotopes: Challenges and future directions." Environmental Toxicology and Chemistry 37(1): 166-174.
0730-7268
1552-8618
http://hdl.handle.net/2027.42/141144
doi:10.1002/etc.3941
Environmental Toxicology and Chemistry
Hobson KA, Clark RG. 1992. Assessing avian diets using stable isotopes I: Turnover of C in tissues. Condor 94: 181 â 188.
Longcore JR, Haines TA, Halteman WA. 2007. Mercury in tree swallow food, eggs, bodies, and feathers at Acadia National Park, Maine, and an EPA superfund site, Ayer, Massachusetts. Environ Monit Assess 126: 129 â 143.
Fair JM, Paul E, Jones J, Council O. 2010. Guidelines to the use of wild birds in research. Ornithological Council, Washington, DC, USA.
Tsui MTK, Blum JD, Kwon SY, Finlay JC, Balogh SJ, Nollet YH. 2013. Photodegradation of methylmercury in stream ecosystems. Limnol Oceanogr 58: 13 â 22.
Zheng W, Obrist D, Weis D, Bergquist BA. 2016. Mercury isotope compositions across North American forests. Glob Biogeochem Cycles 30: 1475 â 1492.
Rodríguezâ González P, Epov VN, Bridou R, Tessier E, Guyoneaud R, Monperrus M, Amouroux D. 2009. Speciesâ specific stable isotope fractionation of mercury during Hg(II) methylation by an anaerobic bacteria ( Desulfobulbus propionicus ) under dark conditions. Environ Sci Technol 43: 9183 â 9188.
Perrot V, Bridou R, Pedrero Z, Guyoneaud R, Monperrus M, Amouroux D. 2015. Identical Hg isotope mass dependent fractionation signature during methylation by sulfateâ reducing bacteria in sulfate and sulfateâ free environment. Environ Sci Technol 49: 1365 â 1373.
Janssen SE, Schaefer JK, Barkay T, Reinfelder JR. 2016. Fractionation of mercury stable isotopes during microbial methylmercury production by ironâ and sulfateâ reducing bacteria. Environ Sci Technol 50: 8077 â 8083.
Roy V, Amyot M, Carignan R. 2009. Beaver ponds increase methylmercury concentrations in Canadian shield streams along vegetation and pondâ age gradients. Environ Sci Technol 43: 5605 â 5611.
Tsui MTK, Finlay JC, Nater EA. 2008. Effects of stream water chemistry and tree species on release and methylation of mercury during litter decomposition. Environ Sci Technol 42: 8692 â 8697.
Bergquist BA, Blum JD. 2007. Massâ dependent and â independent fractionation of Hg isotopes by photoreduction in aquatic systems. Science 318: 417 â 420.
Peckenham JM, Kahl JS, Nelson SJ, Johnson KB, Haines TA. 2007. Landscape controls on mercury in streamwater at Acadia National Park, USA. Environ Monit Assess 126: 97 â 104.
Kwon SY, Blum JD, Chen CY, Meattey DE, Mason RP. 2014. Exposure pathways of methylmercury in estuarine food webs in the northeastern U.S. Environ Sci Technol 48: 10089 â 10097.
Kwon SY, Blum JD, Chirby M, Chesney E. 2013. Application of mercury isotopes for tracing trophic transfer and internal distribution of mercury in marine fish feeding experiments. Environ Toxicol Chem 32: 2322 â 2330.
Hobson KA, Clark RG. 1992. Assessing avian diets using stable isotopes II: Factors influencing dietâ tissue fractionation. Condor 94: 189 â 197.
Hopkins WA, Bodinof C, Budischak S, Perkins C. 2013. Nondestructive indices of mercury exposure in three species of turtles occupying different trophic niches downstream from a former chloralkali. Ecotoxicology 22: 22 â 32.
Yates DE, Mayack DT, Munney K, Evers DC, Major A, Kaur T, Taylor RJ. 2005. Mercury levels in mink ( Mustela vison ) and river otter ( Lontra canadensis ) from northeastern North America. Ecotoxicology 14: 263 â 274.
Akagi H, Malm O, Branches FJP, Kinjo Y, Kashima Y, Guimaraes JRD, Oliveira RB, Haraguchi K, Pfeiffer WC, Takizawa Y, Kato H. 1995. Human exposure to mercury due to goldmining in the Tapajos River basin, Amazon, Brazil: Speciation of mercury in human hair, blood and urine. Water Air Soil Pollut 80: 85 â 94.
Laffont L, Sonke JE, Maurice L, Hintelmann H, Pouilly M, Bacarreza YS, Perez T, Behra P. 2009. Anomalous mercury isotopic compositions of fish and human hair in the Bolivian Amazon. Environ Sci Technol 43: 8985 â 8990.
Sherman LS, Blum JD, Franzblau A, Basu N. 2013. New insight into biomarkers of human mercury exposure using naturally occurring mercury stable isotopes. Environ Sci Technol 47: 3403 â 3409.
Li M, Sherman LS, Blum JD, Grandjean P, Mikkelsen B, Weihe P, Sunderland EM, Shine JP. 2014. Assessing sources of human methylmercury exposure using stable mercury isotopes. Environ Sci Technol 48: 8800 â 8806.
Day RD, Roseneau DG, Berail S, Hobson KA, Donard OFX, Vander Pol SS, Pugh RS, Moors AJ, Long SE, Becker PR. 2012. Mercury stable isotopes in seabird eggs reflect a gradient from terrestrial geogenic to oceanic mercury reservoirs. Environ Sci Technol 46: 5327 â 5335.
Perrot V, Pastukhov MV, Epov VN, Husted S, Donard OFX, Amouroux D. 2012. Higher massâ independent isotope fractionation of methylmercury in the pelagic food web of Lake Baikal (Russia). Environ Sci Technol 46: 5902 â 5911.
Eaglesâ Smith CA, Ackerman JT, Yee J, Adelsbach TL. 2009. Mercury demethylation in waterbird livers: Doseâ response thresholds and differences among species. Environ Toxicol Chem 28: 568 â 577.
Eaglesâ Smith CA, Ackerman JT, Adelsbach TL, Takekawa JY, Miles AK, Keister RA. 2008. Mercury correlations among six tissues for four waterbird species breeding in San Francisco Bay, California, USA. Environ Toxicol Chem 27: 2136 â 2153.
Fournier F, Karasov WH, Kenow KP, Meyer MW, Hines RK. 2002. The oral bioavailability and toxicokinetics of methylmercury in common loon ( Gavia immer ) chicks. Comp Biochem Physiol A Mol Integr Physiol 133: 703 â 714.
Scheuhammer AM, Meyer MW, Sandheinrich MB, Murray MW. 2007. Effects of environmental methylmercury on the health of wild birds, mammals, and fish. Ambio 36: 12 â 19.
Mitchell CPJ, Branfireun BA, Kolka RK. 2008. Spatial characteristics of net methylmercury production hot spots in peatlands. Environ Sci Technol 42: 1010 â 1016.
Kahle S, Becker PH. 1999. Bird blood as bioindicator for mercury in the environment. Chemosphere 39: 2451 â 2457.
Evers DC, Burgess NM, Champoux L, Hoskins B, Major A, Goodale WM, Taylor RJ, Poppenga R, Daigle T. 2005. Patterns and interpretation of mercury exposure in freshwater avian communities in northeastern North America. Ecotoxicology 14: 193 â 221.
Jackson AK, Evers DC, Etterson MA, Condon AM, Folsom SB, Detweiler J, Schmerfeld J, Cristol DA. 2011. Mercury exposure affects the reproductive success of a freeâ living terrestrial songbird, the Carolina wren ( Thryothorus ludovicianus ). Auk 128: 759 â 769.
Blum JD, Sherman LS, Johnson MW. 2014. Mercury isotopes in earth and environmental sciences. Annu Rev Earth Planet Sci 42: 249 â 269.
Tsui MTK, Blum JD, Kwon SY, Finlay JC, Balogh SJ, Nollet YH. 2012. Sources and transfers of methylmercury in adjacent river and forest food webs. Environ Sci Technol 46: 10957 â 10964.
Tsui MTK, Blum JD, Finlay JC, Balogh SJ, Power ME, Palen WJ, Nollet YH. 2014. Variation in terrestrial and aquatic sources of methylmercury in stream predators as revealed by stable mercury isotopes. Environ Sci Technol 48: 10128 â 10135.
Kwon SY, Blum JD, Carvan MJ, Basu N, Head JA, Madanjian CP, David SR. 2012. Absence of fractionation of mercury isotopes during trophic transfer of methylmercury to freshwater fish in captivity. Environ Sci Technol 46: 7527 â 7534.
Li M, Schartup AT, Valberg AP, Ewald JD, Krabbenhoft DP, Yin R, Balcom PH, Sunderland EM. 2016. Environmental origins of methylmercury accumulated in subarctic estuarine fish indicated by mercury stable isotopes. Environ Sci Technol 50: 11559 â 11568.
Yin R, Feng X, Zhang J, Pan K, Wang W, Li X. 2016. Using mercury isotopes to understand the bioaccumulation of Hg in the subtropical Pearl River Estuary, South China. Chemosphere 147: 173 â 179.
Bank MS, Burgess JR, Evers DC, Loftin CS. 2007. Mercury contamination of biota from Acadia National Park, Maine: A review. Environ Monit Assess 126: 105 â 115.
Calhoun AJK, Cormier JE, Owen RB, O’Connell AF, Roman CT, Tiner RW. 1994. The Wetlands of Acadia National Park and Vicinity. Publication Series 21, Maine Agricultural and Forest Experiment Station, Orono, Maine, USA.
Rimmer CC, McFarland KP, Evers DC, Miller EK, Aubry Y, Busby D, Taylor RJ. 2005. Mercury concentrations in Bicknell’s thrush and other insectivorous passerines in montane forests of northeastern North America. Ecotoxicology 14: 223 â 240.
Wayland M, Garciaâ Fernandez AJ, Neugebauer E, Gilchrist HG. 2001. Concentrations of cadmium, mercury, and selenium in blood, liver, and kidney of common eider ducks from the Canadian arctic. Environ Monit Assess 71: 255 â 8267.
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spelling ftumdeepblue:oai:deepblue.lib.umich.edu:2027.42/141144 2024-09-15T17:52:05+00:00 Understanding sources of methylmercury in songbirds with stable mercury isotopes: Challenges and future directions Tsui, Martin Tsz‐ki Adams, Evan M. Jackson, Allyson K. Evers, David C. Blum, Joel D Balogh, Steven J. 2018-01 application/pdf http://hdl.handle.net/2027.42/141144 https://doi.org/10.1002/etc.3941 unknown Maine Agricultural and Forest Experiment Station Wiley Periodicals, Inc. Tsui, Martin Tsz‐ki Adams, Evan M.; Jackson, Allyson K.; Evers, David C.; Blum, Joel D.; Balogh, Steven J. (2018). "Understanding sources of methylmercury in songbirds with stable mercury isotopes: Challenges and future directions." Environmental Toxicology and Chemistry 37(1): 166-174. 0730-7268 1552-8618 http://hdl.handle.net/2027.42/141144 doi:10.1002/etc.3941 Environmental Toxicology and Chemistry Hobson KA, Clark RG. 1992. Assessing avian diets using stable isotopes I: Turnover of C in tissues. Condor 94: 181 â 188. Longcore JR, Haines TA, Halteman WA. 2007. Mercury in tree swallow food, eggs, bodies, and feathers at Acadia National Park, Maine, and an EPA superfund site, Ayer, Massachusetts. Environ Monit Assess 126: 129 â 143. Fair JM, Paul E, Jones J, Council O. 2010. Guidelines to the use of wild birds in research. Ornithological Council, Washington, DC, USA. Tsui MTK, Blum JD, Kwon SY, Finlay JC, Balogh SJ, Nollet YH. 2013. Photodegradation of methylmercury in stream ecosystems. Limnol Oceanogr 58: 13 â 22. Zheng W, Obrist D, Weis D, Bergquist BA. 2016. Mercury isotope compositions across North American forests. Glob Biogeochem Cycles 30: 1475 â 1492. Rodríguezâ González P, Epov VN, Bridou R, Tessier E, Guyoneaud R, Monperrus M, Amouroux D. 2009. Speciesâ specific stable isotope fractionation of mercury during Hg(II) methylation by an anaerobic bacteria ( Desulfobulbus propionicus ) under dark conditions. Environ Sci Technol 43: 9183 â 9188. Perrot V, Bridou R, Pedrero Z, Guyoneaud R, Monperrus M, Amouroux D. 2015. Identical Hg isotope mass dependent fractionation signature during methylation by sulfateâ reducing bacteria in sulfate and sulfateâ free environment. Environ Sci Technol 49: 1365 â 1373. Janssen SE, Schaefer JK, Barkay T, Reinfelder JR. 2016. Fractionation of mercury stable isotopes during microbial methylmercury production by ironâ and sulfateâ reducing bacteria. Environ Sci Technol 50: 8077 â 8083. Roy V, Amyot M, Carignan R. 2009. Beaver ponds increase methylmercury concentrations in Canadian shield streams along vegetation and pondâ age gradients. Environ Sci Technol 43: 5605 â 5611. Tsui MTK, Finlay JC, Nater EA. 2008. Effects of stream water chemistry and tree species on release and methylation of mercury during litter decomposition. Environ Sci Technol 42: 8692 â 8697. Bergquist BA, Blum JD. 2007. Massâ dependent and â independent fractionation of Hg isotopes by photoreduction in aquatic systems. Science 318: 417 â 420. Peckenham JM, Kahl JS, Nelson SJ, Johnson KB, Haines TA. 2007. Landscape controls on mercury in streamwater at Acadia National Park, USA. Environ Monit Assess 126: 97 â 104. Kwon SY, Blum JD, Chen CY, Meattey DE, Mason RP. 2014. Exposure pathways of methylmercury in estuarine food webs in the northeastern U.S. Environ Sci Technol 48: 10089 â 10097. Kwon SY, Blum JD, Chirby M, Chesney E. 2013. Application of mercury isotopes for tracing trophic transfer and internal distribution of mercury in marine fish feeding experiments. Environ Toxicol Chem 32: 2322 â 2330. Hobson KA, Clark RG. 1992. Assessing avian diets using stable isotopes II: Factors influencing dietâ tissue fractionation. Condor 94: 189 â 197. Hopkins WA, Bodinof C, Budischak S, Perkins C. 2013. Nondestructive indices of mercury exposure in three species of turtles occupying different trophic niches downstream from a former chloralkali. Ecotoxicology 22: 22 â 32. Yates DE, Mayack DT, Munney K, Evers DC, Major A, Kaur T, Taylor RJ. 2005. Mercury levels in mink ( Mustela vison ) and river otter ( Lontra canadensis ) from northeastern North America. Ecotoxicology 14: 263 â 274. Akagi H, Malm O, Branches FJP, Kinjo Y, Kashima Y, Guimaraes JRD, Oliveira RB, Haraguchi K, Pfeiffer WC, Takizawa Y, Kato H. 1995. Human exposure to mercury due to goldmining in the Tapajos River basin, Amazon, Brazil: Speciation of mercury in human hair, blood and urine. Water Air Soil Pollut 80: 85 â 94. Laffont L, Sonke JE, Maurice L, Hintelmann H, Pouilly M, Bacarreza YS, Perez T, Behra P. 2009. Anomalous mercury isotopic compositions of fish and human hair in the Bolivian Amazon. Environ Sci Technol 43: 8985 â 8990. Sherman LS, Blum JD, Franzblau A, Basu N. 2013. New insight into biomarkers of human mercury exposure using naturally occurring mercury stable isotopes. Environ Sci Technol 47: 3403 â 3409. Li M, Sherman LS, Blum JD, Grandjean P, Mikkelsen B, Weihe P, Sunderland EM, Shine JP. 2014. Assessing sources of human methylmercury exposure using stable mercury isotopes. Environ Sci Technol 48: 8800 â 8806. Day RD, Roseneau DG, Berail S, Hobson KA, Donard OFX, Vander Pol SS, Pugh RS, Moors AJ, Long SE, Becker PR. 2012. Mercury stable isotopes in seabird eggs reflect a gradient from terrestrial geogenic to oceanic mercury reservoirs. Environ Sci Technol 46: 5327 â 5335. Perrot V, Pastukhov MV, Epov VN, Husted S, Donard OFX, Amouroux D. 2012. Higher massâ independent isotope fractionation of methylmercury in the pelagic food web of Lake Baikal (Russia). Environ Sci Technol 46: 5902 â 5911. Eaglesâ Smith CA, Ackerman JT, Yee J, Adelsbach TL. 2009. Mercury demethylation in waterbird livers: Doseâ response thresholds and differences among species. Environ Toxicol Chem 28: 568 â 577. Eaglesâ Smith CA, Ackerman JT, Adelsbach TL, Takekawa JY, Miles AK, Keister RA. 2008. Mercury correlations among six tissues for four waterbird species breeding in San Francisco Bay, California, USA. Environ Toxicol Chem 27: 2136 â 2153. Fournier F, Karasov WH, Kenow KP, Meyer MW, Hines RK. 2002. The oral bioavailability and toxicokinetics of methylmercury in common loon ( Gavia immer ) chicks. Comp Biochem Physiol A Mol Integr Physiol 133: 703 â 714. Scheuhammer AM, Meyer MW, Sandheinrich MB, Murray MW. 2007. Effects of environmental methylmercury on the health of wild birds, mammals, and fish. Ambio 36: 12 â 19. Mitchell CPJ, Branfireun BA, Kolka RK. 2008. Spatial characteristics of net methylmercury production hot spots in peatlands. Environ Sci Technol 42: 1010 â 1016. Kahle S, Becker PH. 1999. Bird blood as bioindicator for mercury in the environment. Chemosphere 39: 2451 â 2457. Evers DC, Burgess NM, Champoux L, Hoskins B, Major A, Goodale WM, Taylor RJ, Poppenga R, Daigle T. 2005. Patterns and interpretation of mercury exposure in freshwater avian communities in northeastern North America. Ecotoxicology 14: 193 â 221. Jackson AK, Evers DC, Etterson MA, Condon AM, Folsom SB, Detweiler J, Schmerfeld J, Cristol DA. 2011. Mercury exposure affects the reproductive success of a freeâ living terrestrial songbird, the Carolina wren ( Thryothorus ludovicianus ). Auk 128: 759 â 769. Blum JD, Sherman LS, Johnson MW. 2014. Mercury isotopes in earth and environmental sciences. Annu Rev Earth Planet Sci 42: 249 â 269. Tsui MTK, Blum JD, Kwon SY, Finlay JC, Balogh SJ, Nollet YH. 2012. Sources and transfers of methylmercury in adjacent river and forest food webs. Environ Sci Technol 46: 10957 â 10964. Tsui MTK, Blum JD, Finlay JC, Balogh SJ, Power ME, Palen WJ, Nollet YH. 2014. Variation in terrestrial and aquatic sources of methylmercury in stream predators as revealed by stable mercury isotopes. Environ Sci Technol 48: 10128 â 10135. Kwon SY, Blum JD, Carvan MJ, Basu N, Head JA, Madanjian CP, David SR. 2012. Absence of fractionation of mercury isotopes during trophic transfer of methylmercury to freshwater fish in captivity. Environ Sci Technol 46: 7527 â 7534. Li M, Schartup AT, Valberg AP, Ewald JD, Krabbenhoft DP, Yin R, Balcom PH, Sunderland EM. 2016. Environmental origins of methylmercury accumulated in subarctic estuarine fish indicated by mercury stable isotopes. Environ Sci Technol 50: 11559 â 11568. Yin R, Feng X, Zhang J, Pan K, Wang W, Li X. 2016. Using mercury isotopes to understand the bioaccumulation of Hg in the subtropical Pearl River Estuary, South China. Chemosphere 147: 173 â 179. Bank MS, Burgess JR, Evers DC, Loftin CS. 2007. Mercury contamination of biota from Acadia National Park, Maine: A review. Environ Monit Assess 126: 105 â 115. Calhoun AJK, Cormier JE, Owen RB, O’Connell AF, Roman CT, Tiner RW. 1994. The Wetlands of Acadia National Park and Vicinity. Publication Series 21, Maine Agricultural and Forest Experiment Station, Orono, Maine, USA. Rimmer CC, McFarland KP, Evers DC, Miller EK, Aubry Y, Busby D, Taylor RJ. 2005. Mercury concentrations in Bicknell’s thrush and other insectivorous passerines in montane forests of northeastern North America. Ecotoxicology 14: 223 â 240. Wayland M, Garciaâ Fernandez AJ, Neugebauer E, Gilchrist HG. 2001. Concentrations of cadmium, mercury, and selenium in blood, liver, and kidney of common eider ducks from the Canadian arctic. Environ Monit Assess 71: 255 â 8267. IndexNoFollow Trophic transfer Songbird Wetland Methylation Isotopic fractionation Natural Resources and Environment Biological Chemistry Science Article 2018 ftumdeepblue https://doi.org/10.1002/etc.3941 2024-07-30T04:06:07Z Mercury (Hg) stable isotope analysis is an emerging technique that has contributed to a better understanding of many aspects of the biogeochemical cycling of Hg in the environment. However, no study has yet evaluated its usefulness in elucidating the sources of methylmercury (MeHg) in songbird species, a common organism for biomonitoring of Hg in forested ecosystems. In the present pilot study, we examined stable mercury isotope ratios in blood of 4 species of songbirds and the invertebrates they are likely foraging on in multiple habitats in a small watershed of mixed forest and wetlands in Acadia National Park in Maine (USA). We found distinct isotopic signatures of MeHg in invertebrates (both massâ dependent fractionation [as δ202Hg] and massâ independent fractionation [as Î 199Hg]) among 3 interconnected aquatic habitats. It appears that the Hg isotopic compositions in bird blood cannot be fully accounted for by the isotopic compositions of MeHg in lower trophic levels in each of the habitats examined. Furthermore, the bird blood isotope results cannot be simply explained by an isotopic offset as a result of metabolic fractionation of δ202Hg (e.g., internal demethylation). Our results suggest that many of the birds sampled obtain MeHg from sources outside the habitat they were captured in. Our findings also indicate that massâ independent fractionation is a more reliable and conservative tracer than massâ dependent fractionation for identifying sources of MeHg in bird blood. The results demonstrate the feasibility of Hg isotope studies of songbirds but suggest that larger numbers of samples and an expanded geographic area of study may be required for conclusive interpretation. Environ Toxicol Chem 2018;37:166â 174. © 2017 SETAC Peer Reviewed https://deepblue.lib.umich.edu/bitstream/2027.42/141144/1/etc3941.pdf https://deepblue.lib.umich.edu/bitstream/2027.42/141144/2/etc3941_am.pdf Article in Journal/Newspaper Arctic University of Michigan: Deep Blue Environmental Toxicology and Chemistry 37 1 166 174