Local weather change and overfishing enhance neurotoxic results in marine predators
Sunderland, E.M., Li, M. & Bullard, Ok. Decadal modifications within the edible provide of seafood and methylmercury publicity in the USA. About. Well being Perspective. 126, 017006 (2018).
Horowitz, H.M. et al. A brand new mechanism for atmospheric mercury redox chemistry: implications for the worldwide mercury stability. Atmos. Chem. Phys. 17, 6353-6371 (2017).
Bellanger, M. et al. Financial advantages of controlling methylmercury publicity in Europe: the financial worth of stopping neurotoxicity. About. Well being 12, three (2013).
Streets, D. et al. World and regional traits in mercury emissions and concentrations. Atmos. About. 201, 417-427 (2019).
Lotze, H. Ok. & Milewski, I. Two centuries of human impacts and successive modifications within the North Atlantic meals net. College. Appl. 14, 1428-1447 (2004).
Schartup, A. T. et al. A mannequin for the absorption of methylmercury and trophic switch by marine plankton. About. Sci. Technol. 52, 654-662 (2018).
Smith, B.E. & Hyperlink, J.S. The trophic dynamics of 50 species of finfish and a couple of squid on the continental shelf of the northeastern United States. NOAA Technical Memorandum NMFS-NE-21 (Nationwide Marine Fisheries Service, 2010).
Pershing, A.J. et al. The sluggish adaptation to fast warming is resulting in the collapse of the cod fishery within the Gulf of Maine. Science 350, 809-812 (2015).
Dijkstra, J.A. et al. Experimental and pure warming raises mercury ranges in estuarine fish. PLoS ONE eight, e58401 (2013).
Maulvault, A. L. et al. Bioaccumulation and elimination of mercury in juvenile sea bass (Dicentrarchus labrax) in a hotter setting. About. Res. 149, 77-85 (2016).
Cheung, W. W. L. et al. Projection of impacts on world marine biodiversity in local weather change eventualities. Fish Fish. 10, 235-251 (2009).
Sunderland, E.M. et al. Sources of mercury and develop into within the Gulf of Maine. About. Res. 119, 27-41 (2012).
Zhang, Y. et al. Noticed lower in atmospheric mercury resulting from world decline in anthropogenic emissions. Proc. Natl Acad. Sci. USA 113, 526-531 (2016).
Restrepo, V. et al. Up to date estimate of the expansion curve of Atlantic bluefin tuna. Aquat. Residing useful resource. 23, 335-342 (2010).
Cross, F.A., Evans, D.W. & Barber, R.T. Decline, the mercury a long time in grownup blue fish (1972-2011) from the mid-Atlantic coast of the American setting. Sci. Technol. 49, 9064-9072 (2015).
Lee, C.-S. et al. The decline in mercury ranges in bluefin tuna displays the discount in emissions within the North Atlantic Ocean. About. Sci. Technol. 50, 12825 to 12830 (2016).
Hammerschmidt, C.R., Finiguerra, MB, Weller, R.L. and Fitzgerald, W. F. Accumulation of methylmercury in plankton on the continental margin of the northwestern Atlantic Ocean. About. Sci. Technol. 47, 3671-3677 (2013).
Hellou, J., Fancey, L. and Payne, J. Concentrations of twenty-four parts in bluefin tuna, Thunnus thynnus, from the Northwest Atlantic. Chemosphere 24, 211-218 (1992).
Harding, G., Dalziel, J. and Vass, P. Bioaccumulation of methylmercury within the marine meals net of the Bay of Fundy, Gulf of Maine. PLoS ONE 13, e0197220 (2018).
Peterson, C.L., Klawe, W.L. & Sharp, G.D. Mercury in tuna: evaluation. Bull fish. 71, 603-613 (1973).
Mendez, E., H. Giudice, A. Pereira, G. Inocente and DD Medina, relationship between whole mercury content material and fish weight in swordfish (Xiphias gladius) caught in southwestern California. Atlantic Ocean. J. Meals Compos. Anal. 14, 453-460 (2001).
Lavoie, R.A., Jardine, T.D., Chumchal, M.M., Kidd, Ok.A. and Campbell, L.M. Biomagnification of mercury in aquatic meals webs: a worldwide meta-analysis. About. Sci. Technol. 47, 13385-13394 (2013).
Hoen, D.Ok. et al. Trophic enrichment components of 15N amino acids from 4 giant carnivorous fish. J. Exp. Mar Biol. College. 453, 76-83 (2014).
Streets, D.G. et al. Whole mercury launched into the setting by human actions. About. Sci. Technol. 51, 5969-5977 (2017).
Sunderland, E. M. & Mason, R. P. Human impacts on mercury concentrations within the excessive seas. Glob. Biogéochem. Cycles 21, GB4022 (2007).
Kitchell, J.F., Stewart, D.J. and Weininger, D. Functions of a bioenergetic mannequin to yellow perch (Perca flavescens) and walleye (Stizostedion vitreum vitreum). J. Fish. Res. Council can. 34, 1922-1935 (1977).
Nøttestad, L., J. Giske, J.C. Holst and Huse, G. A length-based speculation to feed migrations of pelagic fish. Can. J. Fish. Aquat. Sci. 56, 26-34 (1999).
Rudstam, L. G. Exploring the dynamics of herring consumption within the Baltic: functions of an vitality mannequin of fish development. Kieler Meeresforschungen Sonderheft 6, 312-322 (1988).
Block, B.A. et al. Migratory actions, depth preferences and thermal biology of Atlantic bluefin tuna. Science 293, 1310-1314 (2001).
Neilson, J. D. et al. Seasonal distributions and Northwest Atlantic swordfish migrations: inferences from the mixing of satellite tv for pc archival tagging research. PLoS ONE 9, e112736 (2014).
Bowman, Ok.L., Hammerschmidt, C.R., Lamborg, C.H. & Swarr, G. Mercury within the North Atlantic: the zonal and southern sections of GEOTRACES (United States). Deep Sea Res. Half II Prime. Stud. Oceanogr. 116, 251-261 (2015).
Scharf, F.S., Juanes, F. & Rountree, R. Prey dimension / dimension relationships of marine fish predators: interspecific variation and results of ontogeny and physique dimension on the width of the trophic area of interest. Mar. Ecol. Program. Ser. 208, 229-248 (2000).
Younger, J., Lansdell, M., Riddoch, S. and Revill, A. Ecology of the weight-reduction plan of large-leafed swordfish, Xiphias gladius, off jap Australia, in relationship with bodily and environmental variables. Taurus. Mar. Sci. 79, 793-809 (2006).