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Environmental sensitivity of fish Otolith Microchemistry
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Kennedy Brian P,
Blum Joel D,
Folt Carol L, Nislow Keith H
Canadian Journal of Fisheries and Aquatic Sciences. 2000 57(11). p.2280
Rapid growth causes abnormal vaterite formation in farmed fish otoliths
Reimer T.,
Dempster T.,
Wargelius A.,
Fjelldal P. G.,
Hansen T.,
Glover K. A.,
Solberg M. F., Swearer S. E.
Journal of Experimental Biology. 2017
Changes in otolith microchemistry of the Japanese eel, Anguitta japonica, during its migration from the ocean to the rivers of Taiwan
Tzeng W. N., Tsai Y. C.
Journal of Fish Biology. 1994 45(4). p.671
Reprint of Using statolith elemental signatures to confirm ontogenetic migrations of the squid Doryteuthis gahi around the Falkland Islands (Southwest Atlantic)
Jones Jessica B.,
Arkhipkin Alexander I.,
Marriott Andy L., Pierce Graham J.
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Wu Wenjie,
Chaput Romain,
Lundquist Carolyn J.,
Montaño Orozco Mireya M., Jeffs Andrew G.
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Factors influencing otolith strontium/calcium ratios in Anguilla japonica elvers
Kawakami Yutaka,
Mochioka Noritaka,
Morishita Koichiro,
Tajima Toshihiro,
Nakagawa Hisaki,
Toh Hidetoshi, Nakazono Akinobu
Environmental Biology of Fishes. 1998 52(1-3). p.299
Multi-way analysis of trace elements in fish otoliths to track migratory patterns
Gemperline Paul J,
Rulifson Roger A, Paramore Lee
Chemometrics and Intelligent Laboratory Systems. 2002 60(1-2). p.135
Spatio‐temporal variation in the elemental compositions of otoliths of southern bluefin tuna Thunnus maccoyii in the Indian Ocean and its ecological implication
Wang C. H.,
Lin Y. T.,
Shiao J. C.,
You C. F., Tzeng W. N.
Journal of Fish Biology. 2009 75(6). p.1173
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Avigliano Esteban,
Leisen Mathieu,
Romero Rurik,
Carvalho Barbara,
Velasco Gonzalo,
Vianna Marcelo,
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Experimental assessment of the effect of temperature and salinity on elemental composition of otoliths using laser ablation ICPMS
Fowler Anthony J.,
Campana Steven E.,
Thorrold Simon R., Jones Cynthia M.
Canadian Journal of Fisheries and Aquatic Sciences. 1995 52(7). p.1431
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Mateo Ivan,
Durbin Edward G.,
Bengtson David A.,
Kingsley Richard,
Swart Peter K., Durant Daisy
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An investigation of chronological differences in the deposition of trace metals in the otoliths of two temperate reef fishes.
Dove S.G,
Gillanders B.M, Kingsford M.J
Journal of Experimental Marine Biology and Ecology. 1996 205(1-2). p.15
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Škeljo Frane,
Ferri Josipa,
Brčić Jure,
Petrić Mirela, Jardas Ivan
Scientia Marina. 2012 76(3). p.587
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Wedding B. B.,
Forrest A. J.,
Wright C.,
Grauf S.,
Exley P., Poole S. E.
Marine and Freshwater Research. 2014 65(10). p.894
Coral Reef Fishes (2002)
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Cavole LM,
Miller JA,
Salinas-de-León P,
Aburto-Oropeza O,
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Gordoa Ana,
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Radtke R.L.,
Townsend D.W.,
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Farrell Jacqueline, Campana Steven E.
Comparative Biochemistry and Physiology Part A: Physiology. 1996 115(2). p.103
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American Journal of Physiology-Regulatory, Integrative and Comparative Physiology. 1999 277(1). p.R123
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Sudo Ryusuke,
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Zoological Science. 2011 28(3). p.180
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Elder Kathryn L.,
Jones Glenn A., Bolz George
Paleoceanography. 1996 11(3). p.359
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Granzotto Angela,
Franceschini Gianluca,
Malavasi Stefano,
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Italian Journal of Zoology. 2003 70(1). p.5
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Canadian Journal of Fisheries and Aquatic Sciences. 1995 52(7). p.1421
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Friedland Kevin D,
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Canadian Journal of Fisheries and Aquatic Sciences. 1998 55(5). p.1158
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Environmental Biology of Fishes. 2000 58(2). p.195
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Fisheries Research. 1999 43(1-3). p.165
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Environmental Biology of Fishes. 1995 43(4). p.393
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Morgan Steven G.,
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Journal of Shellfish Research. 2009 28(1). p.23
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Korostelev N. B., Orlov A. M.
Oceanology. 2020 60(6). p.798
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Vignon Matthias,
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Pecheyran Christophe,
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Journal of Experimental Biology. 2023 226(13).
Eel Biology (2003)
The effect of otolith storage methods on the concentrations of elements detected by laser‐ablation ICPMS
Milton D. A., Chenery† S. R.
Journal of Fish Biology. 1998 53(4). p.785
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Izzo Christopher,
Doubleday Zoë A., Gillanders Bronwyn M.
Marine and Freshwater Research. 2016 67(7). p.1072
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Pearcy William G, Miller Jessica A
Northwestern Naturalist. 2018 99(2). p.101
Age estimation of barramundi (
Wright C.,
Wedding B. B.,
Grauf S., Whybird O. J.
Marine and Freshwater Research. 2021 72(9). p.1268
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Miles N. G.,
West R. J., Norman M. D.
Marine and Freshwater Research. 2009 60(9). p.904
Temperature effects on the incorporation of strontium in otolith of Japanese eel Anguilla japonica
Tzeng W. N.
Journal of Fish Biology. 1994 45(6). p.1055
Environmental effects on primary increment formation in the otoliths of newlyhatched Arctic charr
Radtke R., Fey D. P.
Journal of Fish Biology. 1996 48(6). p.1238
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Avigliano Esteban,
Maichak de Carvalho Barbara,
Leisen Mathieu,
Romero Rurik,
Velasco Gonzalo,
Vianna Marcelo,
Barra Fernando, Volpedo Alejandra Vanina
Estuarine, Coastal and Shelf Science. 2017 194 p.92
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Avigliano E.,
Pisonero J.,
Sánchez S.,
Dománico A., Volpedo A. V.
River Research and Applications. 2018 34(7). p.863
