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Reviews on Environmental Health

Editor-in-Chief: Carpenter, David O. / Sly, Peter

Editorial Board: Brugge, Doug / Edwards, John W. / Field, R.William / Garbisu, Carlos / Hales, Simon / Horowitz, Michal / Lawrence, Roderick / Maibach, H.I. / Shaw, Susan / Tao, Shu / Tchounwou, Paul B.

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Volume 31, Issue 1


Connecting mercury science to policy: from sources to seafood

Celia Y. Chen / Charles T. Driscoll
  • Department of Civil and Environmental Engineering, Syracuse University, Syracuse NY, 13244, USA
  • Other articles by this author:
  • De Gruyter OnlineGoogle Scholar
/ Kathleen F. Lambert / Robert P. Mason
  • Department of Marine Sciences, University of Connecticut, 1080 Shennecossett Road, Groton, CT 06340, USA
  • Other articles by this author:
  • De Gruyter OnlineGoogle Scholar
/ Elsie M. Sunderland
Published Online: 2016-01-28 | DOI: https://doi.org/10.1515/reveh-2015-0044


Mercury (Hg) is a global contaminant whose presence in the biosphere has been increased by human activity, particularly coal burning/energy production, mining, especially artisanal scale gold mining, and other industrial activities. Mercury input to the surface ocean has doubled over the past century leading governments and organizations to take actions to protect humans from the harmful effects of this toxic element. Recently, the UN Environmental Program led 128 countries to negotiate and sign a legally binding agreement, the 2013 Minimata Convention, to control Hg emissions and releases to land and water globally. In an effort to communicate science to this emerging international policy, the Dartmouth Superfund Research Program formed the Coastal and Marine Mercury Ecosystem Research Collaborative (C-MERC) in 2010 that brought together more than 70 scientists and policy experts to analyze and synthesize the science on Hg pollution in the marine environment from Hg sources to MeHg in seafood. The synthesis of the science revealed that the sources and inputs of Hg and their pathways to human exposure are largely determined by ecosystem spatial scales and that these spatial scales determine the organizational level of policies. The paper summarizes the four major findings of the report.

Keywords: mercury policy; mercury pollution; minimata treaty; seafood contamination


  • 1.

    Driscoll CT, Han YJ, Chen CY, Evers DC, Lambert KF, et al. Mercury contamination in forest and freshwater ecosystems in the Northeastern United States. Bioscience 2007;57:17–28.Web of ScienceCrossrefGoogle Scholar

  • 2.

    Mason RP, Fitzgerald WF, Morel FMM. The biogeochemical cycling of elemental mercury – anthropogenic influences. Geochimica Et Cosmochimica Acta 1994;58:3191–8.CrossrefGoogle Scholar

  • 3.

    Selin NE, Jacob DJ, Yantosca RM, Strode S, Jaegle L, et al. Global 3-D land-ocean-atmosphere model for mercury: Present-day versus preindustrial cycles and anthropogenic enrichment factors for deposition. Global Biogeochem Cy 2008;22:1–13.Web of ScienceGoogle Scholar

  • 4.

    ATSDR. Priority list of hazardous substances Agency for Toxic Substances and Disease Registry. 2015.Google Scholar

  • 5.

    Karagas MR, Choi AL, Oken E, Horvat M, Schoeny R, et al. Evidence on the human health effects of low level methylmercury exposure. Environ Health Perspect 2012;120:799–806.CrossrefGoogle Scholar

  • 6.

    Mahaffey KR, Sunderland EM, Chan HM, Choi AL, Grandjean P, et al. Balancing the benefits of n-3 polyunsaturated fatty acids and the risks of methylmercury exposure from fish consumption. Nutr Rev 2011;69:493–508.Web of ScienceGoogle Scholar

  • 7.

    Mergler D, Anderson HA, Chan LHM, Mahaffey KR, Murray M, et al. Methylmercury exposure and health effects in humans: A worldwide concern. Ambio 2007;36:3–11.Web of ScienceCrossrefGoogle Scholar

  • 8.

    Nyland JF, Wang SB, Shirley DL, Santos EO, Ventura AM, et al. Fetal and maternal immune responses to methylmercury exposure: A cross-sectional study. Environ Res 2011;111:584–9.Web of ScienceGoogle Scholar

  • 9.

    Chen CY, Stemberger RS, Kamman NC, Mayes BM, Folt CL. Patterns of Hg bioaccumulation and transfer in aquatic food webs across multi-lake studies in the northeast US. Ecotoxicology 2005;14:135–47.CrossrefGoogle Scholar

  • 10.

    Kirk JL, Louis VLS, Hintelmann H, Lehnherr I, Else B, et al. Methylated mercury species in marine waters of the canadian high and sub arctic. Environ Sci Technol 2008;42:8367–73.CrossrefWeb of ScienceGoogle Scholar

  • 11.

    Riget F, Braune B, Bignert A, Wilson S, Aars J, et al. Temporal trends of Hg in Arctic biota, an update. Sci Total Environ 2011;409:3520–6.Google Scholar

  • 12.

    UNEP. Global Mercury Assessment 2013L Sources, Emissions, Releases and Environmental Transport. UNEP Chemicals Branch, Geneva, Switzerland, 2013.Google Scholar

  • 13.

    Bhavsar SP, Gewurtz SB, McGoldrick DJ, Keir MJ, Backus SM. Changes in mercury levels in Great Lakes fish between 1970s and 2007. Environ Sci Technol 2010;44:3273–9.Web of ScienceCrossrefGoogle Scholar

  • 14.

    Carrie J, Wang F, Sanei H, Macdonald RW, Outridge PM, et al. Increasing contaminant burdens in an Arctic fish, Burbot (Lota lota), in a warming climate. Environ Sci Technol 2010;44:316–22.Web of ScienceCrossrefGoogle Scholar

  • 15.

    Conaway CH, Ross JRM, Looker R, Mason RP, Flegal AR. Decadal mercury trends in San Francisco Estuary sediments. Environ Res 2007;105:53–66.CrossrefWeb of ScienceGoogle Scholar

  • 16.

    Gratz LE, Keeler GJ, Miller EK. Long-term relationships between mercury wet deposition and meteorology. Atmos Environ 2009;43:6218–29.CrossrefWeb of ScienceGoogle Scholar

  • 17.

    Greenfield BK, Davis JA, Fairey R, Roberts C, Crane D, et al. Seasonal, interannual, and long-term variation in sport fish contamination, San Francisco Bay. Sci Total Environ 2005;336:25–43.Google Scholar

  • 18.

    Macdonald RW, Harner T, Fyfe J. Recent climate change in the Arctic and its impact on contaminant pathways and interpretation of temporal trend data. Sci Total Environ 2005;342:5–86.Google Scholar

  • 19.

    Sunderland EM, Dalziel J, Heyes A, Branfireun BA, Krabbenhoft DP, et al. Response of a macrotidal estuary to changes in anthropogenic mercury loading between 1850 and 2000. Environ Sci Technol 2010;44:1698–704.Web of ScienceCrossrefGoogle Scholar

  • 20.

    Chen CY, Driscoll CT, Lambert KF, Mason RP, Rardin LR, et al. Sources to seafood: Mercury pollution in the marine environment. Hanover, NH: Toxic Metals Superfund Research Program, Dartmouth College. 2012. Available at: http://www.dartmouth.edu/~toxmetal/C-MERC/.

  • 21.

    Minimata Convention on Mercury: Texts and Annexes. 2014. United Nation Environment Programme GE.14-00280 UNEP/CHEMICALS/2014/1, Publishing Service, United Nations, Geneva Switzerland.Google Scholar

  • 22.

    Driscoll CT, Mason RP, Chan HM, Jacob DJ, Pirrone N. Mercury as a global pollutant: Sources, pathways, and effects. Environ Sci Technol 2013;47:4967–83.Web of ScienceCrossrefGoogle Scholar

About the article

Corresponding author: Celia Y. Chen, Department of Biological Sciences, Dartmouth College, Hanover NH, 03755, USA, E-mail:

Received: 2015-10-13

Accepted: 2015-11-02

Published Online: 2016-01-28

Published in Print: 2016-03-01

Citation Information: Reviews on Environmental Health, Volume 31, Issue 1, Pages 17–20, ISSN (Online) 2191-0308, ISSN (Print) 0048-7554, DOI: https://doi.org/10.1515/reveh-2015-0044.

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