Analysis of environmental conditions and macro-cations composition (Ca, Mg, Na, K, Sr) in the operculum bones of estuarine fishes in the Pomeranian Bay (southern Baltic Sea)

• Autorzy: Tórz A. , Nędzarek A.
• Języki publikacji: EN

Abstrakty

EN

The aim of this study was to show the influence of environmental conditions on the ionic composition of fish bones. The analysis concerned the ionic structural composition of the operculum in fish species with different abiotic habitat preferences. Three species of fish were examined: cod, Gadus morhua L., 1758; sea trout, Salmo trutta morpha trutta L., 1758 and perch, Perca fluviatilis L., 1758. Results from hydrochemical research on salinity in the Pomeranian Bay (Southern Baltic) were also utilized. Using the determined ratios (Ca:Mg, Na:Mg, Sr:Ca and Na:Ca in the operculum and Ca:Mg, Na:Mg and Na:Ca in the waters of the Pomeranian Bay), typical correlations were determined for the analyzed habitat. Macrocation structure in the operculum bones for each species were found to be as follows: - cod: Ca – 32.3%, Mg – 29.8%, Na – 1.4%, K – 0.8%, Sr – 2.1%; - sea trout: Ca – 22.8%, Mg – 13.5%, Na – 0.8%, K – 0.2%, Sr – 1.7%; - perch, Ca – 37.9%, Mg – 15.1%, Na – 2.4%, K – 0.7%, Sr – 1.6%.

Słowa kluczowe

EN

estuarine fishes; macro-cations in operculum; Pomeranian Bay

• Wydawca: Institute of Oceanography University of Gdańsk
• Czasopismo: Oceanological and Hydrobiological Studies
• Rocznik: 2010
• Tom: Vol. 39, No.1
• Strony: 147--159
• Opis fizyczny: bibliogr. 21 poz., tab., wykr.

Twórcy

autor

Tórz A.

autor

Nędzarek A.

• Department of Hydrochemistry and Water Protection West Pomeranian University of Technology ul. K. Królewicza 4 H, 71-550 Szczecin, Poland,

Bibliografia

• 1.Analitical methods for atomic absorbtion spectrophotometry, 1982, Perkin-Elmer, Norwalk, Connecticet, USA
• 2.Arai T., Hirata T., 2006, Differences in the trace elements deposition in otoliths between marineand freshwater-redident Japanese eels, Anguilla Japonica, as determined by laser ablatio ICPMS. Env. Biol. Fish. 75:173-182
• 3.Arai T., Kotake A., Kitamura T., 2005, Migration of anadromus white-spotted charr Salvelinus leucomaenis, as determined by otholit strontium:calcium ratios. Fish. Sci. 71:731-737
• 4.Bijvelds M.J.C., Flik G., Wndelaar Bonga S.E., 1997, Mineral balance in Oreochromis mossambicus: dependence o magnesium in diet and water. Fish Physiol. Biochem. 16:323-331
• 5.Elliott M., Hemingway K.L., 2002, Fishes in Estuaries. Oxford: Blackwell Science Ltd. 636pp
• 6.Forrester G.E., Swearer S.E., 2002, Trace elements in otoliths indicate the use of open-coast versus bay nursery habitats by juvenile California halibut. Mar. Ecol. Prog.. Ser. 241:201-213
• 7.Gillanders B.M., Kingsford M.J., 2003, Spatial variation in elemental composition of otholits of three species of fish (Family Sparidae). Est. Coast. Sh. Sci. 57:1049-1064
• 8.Gillanders B.M., Sanches-Jerez P., Bayle-Sempere J.T., Ramos-Espla A., 2001, Trace elements in otoliths of the two-banded bream from a coastal region in the south-west Mediterranean: ar there differences among locations? J. Fish Biol. 43:333-339
• 9.Humphreys W.F., Jen-Chieh S., Yoshiyuki I., Wann-Nian T., 2006, Can otolith microchemistry reveal whether the blind cave gudgeon, Milyeringa veritas (Elotridae), is diadromus within a subterranean estuary? Environ. Biol .Fish. 75:439-453
• 10.Kraus R.T., Secor D.H., 2004, Incorporation of strontium into otoliths of an estuarine fish. J. Exper. Mar. Biol. Ecol. 302:85-106
• 11.Majewski A., 1972, Hydrological characteristics of estuary waters in the Polish sea-coast. PIHM Work. 105:3-40. (In Polish)
• 12.Mikulski Z., 1967, Participation of river waters in the hydrological balance of the Pomeranian Bay. Bulletin PIHM 10 (109):452-454. (In Polish)
• 13.Rooker J.R., Secor D.H., Zdanowicz V.S., de Metrio G., Orsi Relini L., 2003, Identification of Atlantic bluefin tuna (Thunnus thynnus) stock for putalive nurseries using otolith chemistry. Fish. Oceanogr., 12(2):75-84
• 14.Secor D.H., Rooker J.R., 2000, Is otolith a useful scalar of life cycles in estuarine fishes? Fish. Res. 46:359-37.
• 15.StatSoft Inc., 2006, STATISTICA (data analysis sofware system), version 7.1, www.statsoft.com.
• 16.Thorrold S.R., Jones C.M., Campana S.E., McLaren J.W., Lam J.W.H., 1998, Trace elements signatures in otoliths record natal river of juvenile American shad (Alosa sapidissima). Limnol. Oceanogr. 43:1826-1835
• 17.Thoppe J., Albrektsen S., Hope B., Aksnes A., 2007, Chemical composition, mineral content and amino acid and lipid profiles in bones from various fish species. Comp. Bioch. Physiol. Part B 146:395-401
• 18.Thresher R.E., 1999, Elemental composition of otoliths as a stock delineator in fishes. Fish. Res. 43:165-204
• 19.Tórz A., 2007, Ionic transformations in estuary waters of the Odra River and their influence on ichthyofauna habitat conditions. Szczecin: Agric. Univ. Ltd. D. 244:83pp. (In Polish)
• 20.Volk E.C., Blakley A., Schroder S.L., Kuehner S.M., 2000, Otolith chemistry reflects migratory characteristics of Pacific salmoids: Using otolith core chemistry to distinguish maternal associations with sea and freshwaters. Fish. Res. 46:251-266
• 21.Więcaszek B., Krzykawski S., Keszka S., Antoszek A., 2006, Fish in aquo-culture and aquotourism. Szczecin: Agric. Univ. Ltd. 330pp. (In Polish)