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Assessment of the Toxicity of the Natural and Technogenic Environment for Motor Activity of Daphnia magna

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Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
The Daphnia magna Straus (1820) crustaceans are used in many countries to assess the quality of the environment. Researchers are guided more often by the mortality of individuals. However, the sublethal effects contribute to the development of biological early warning systems (BEWS). A visual method for recording the motor activity of D. magna was proposed. This method has advantages over automated analogs. It is simple, accessible to performers and does not require the use of special instruments. The method was tested under conditions of modeling the lethal and sublethal effects of heavy metal salts (Cu and Zn). The diagnosis of lethal doses is possible after 1 hour of exposure, whereas the death of crustaceans can occur in 3–4 days of the experiment. The effect of sublethal doses of heavy metals becomes statistically significant after 24 (p < 0.05). The sensitivity of the method was confirmed in the studies of the aqueous extracts from the soils contaminated with various heavy metals (heavy metal processing area). The method showed good results in assessing the toxic effect of the waters anthropogenically contaminated with the mineral forms of nitrogen (NH4+and NO3-) in the region of fertilizer production. The maximum inverse correlation between the motor activity and the concentration of ammonium ions in water (-0.83) was shown after 24 hours. Thus, the method of visual assessment of motor activity can be used in environmental monitoring.
Rocznik
Strony
11--16
Opis fizyczny
Bibliogr. 24 poz., tab.
Twórcy
autor
  • Department of Ecology and Nature Management, Institute of Chemistry and Ecology, Vyatka State University, Krasnoarmeyskaya Str. 26, Kirov, 610001, Russia
  • Department of Ecology and Nature Management, Institute of Chemistry and Ecology, Vyatka State University, Krasnoarmeyskaya Str. 26, Kirov, 610001, Russia
Bibliografia
  • 1. Aliouane, Y., el Hassani, A.K., Gary, V., Armengaud, C., Lambin, M., Gauthier, M. 2009. Subchronic exposure of honeybees to sublethal doses of pesticides: Effects on behavior. Environment and Chemistry, 28(1), 113–122.
  • 2. Benedetti, M.F., Miln, C.J., Kinniburgh, D.G., Van Riemsdijk, W.H., Koopal, L.K. 1995. Metal ion binding to humic substances: Application of the non-ideal competitive adsorption model. Environmental Science and Technology, 29(2), 446–457.
  • 3. Biological test method: Acute lethality test using Daphnia spp. 1996. In Environmental Protection Series. Environmental Technology Centre. Environment Canada. Report EPS 1/RM/11.
  • 4. Calabrese, E.J. 2008. Hormesis: why it is important to toxicology and toxicologists. Environmental Toxicology and Chemistry, 27, 1451–1474.
  • 5. Castro, B.B., Sobral, O., Guilhermino, L., Ribeiro, R. 2004. An in situ bioassay integrating individual and biochemical responses using small fish species. Ecotoxicology, 13, 667–681.
  • 6. Di Toro, D.M., Allen, H.E., Bergman, H.L., Meyer, J.S., Paquin, P.R., Santore, R.C. 2001. Biotic ligand model of the acute toxicity of metals. 1. Technical basis. Environmental Toxicology and Chemistry, 20, 2383–2396.
  • 7. Domingues, I., Santos, C.S.A., Ferreira, N.G.C., Machado, L., Oliveira, R., Ferreira, A., Lopes, I., Loureiro, S., Soares, A.M.V.M. 2015. Suitability of enzymatic markers to assess the environmental condition of natural populations of Gambusia affinis and Daphnia magna – a case study. Environmental Monitoring and Assessment, 187(4), 208.
  • 8. Egorova, K.S., Ananikov, V.P. 2017. Toxicity of Metal Compounds: Knowledge and Myths, Organometallics, 36(21), 4071–4090.
  • 9. FR.1.39.2007.03222. 2007. Methods of determining the toxicity of water and water extracts from soils, sewage sludge, waste mortality and fertility change in Daphnia. 2007. Moscow: Akvaros (in Russia).
  • 10. Gravato, C., Guilhermino, L. 2009. Effects of benzo(a)pyrene on seabass (Dicentrarchus labrax L.): biomarkers, growth and behavior. Human and Ecological Risk Assessment, 15, 121–137.
  • 11. Hellou, J. 2011. Behavioural ecotoxicology, an “early warning” signal to assess environmental quality, Environmental Science and Pollution Research, 18, 1–11.
  • 12. ISO 6341:2012. 2012. Water quality – Determination of the inhibition of the mobility of Daphnia magna Straus (Cladocera, Crustacea) – Acute toxicity test. International Organization for Standardization.
  • 13. Jeong, T.-Y., Yoon, D., Kim, S., Kim, H.Y., Kim, S.D. 2018. Mode of action characterization for adverse effect of propranolol in Daphnia magna based on behavior and physiology monitoring and metabolite profiling. Environmental Pollution, 233. 99–108.
  • 14. Kovács, A, Abdel-Hameid, N.-A., Acs, A., Ferincz, Á., Kováts, N. 2012. A novel protocol for assessing aquatic pollution, based on the feeding inhibition of Daphnia magna. Knowledge and Management of Aquatic Ecosystems, 404, 7.
  • 15. Lechelt, M., Blohm, W., Kirschneit, B., Pfeiffer, M., Gresens, E., Liley, J., Holz, R., Lüring, C. 2000. Moldaenke Monitoring of surface water by ultrasensitive Daphnia taximeter. Environmental Toxicology, 15, 390–400.
  • 16. Morgana S., Estévez-Calvar N., Gambardella C., Faimali M., Garaventa, F. 2018. A short-term swimming speed alteration test with nauplii of Artemia franciscana. Ecotoxicology and Environmental Safety, 147, 558–564.
  • 17. Olkova, A.S. 2017. The conditions of cultivation and the variety of test functions of Daphnia magna Straus in bioassay. Water and Ecology, 1, 64–82.
  • 18. Olkova, A.S., Kantor, G.Y., Kutyavina, T.I., Ashikhmina, T.Y. 2018. The importance of maintenance conditions of Daphnia magna Straus as a test organism for ecotoxicological analysis. Environmental Toxicology and Chemistry, 37(2), 376–384.
  • 19. Osswald, J., Carvalho, A. P., Guimarães, L., Guilhermino, L. 2013. Toxic effects of pure anatoxina on biomarkers of rainbow trout, Oncorhynchus mykiss. Toxicon, 70, 162–169.
  • 20. Parolini, M., De Felice, B., Ferrario, C., SalgueiroGonzález, N., Castiglioni, S., Finizio, A., Tremolada, P. 2018. Benzoylecgonine exposure induced oxidative stress and altered swimming behavior and reproduction in Daphnia magna. Environmental Pollution, 232, 236–244.
  • 21. Shashkova, T., L., Grigor’ev, Yu. S. Impact of heavy metals on the trophic activity of daphnia depending on feeding conditions and age of crustaceans. 2013. Contemporary problems of ecology, 6(6), 662–666 (in Russia).
  • 22. Shimizu, N., Ogino, C., Kawanishi, T., Hayashi, Y. 2002. Fractal analysis of Daphnia motion for acute toxicity bioassay. Environmental Toxicology, 17(5), 441–448.
  • 23. Thorslund, J., Jarsjo, J., Wallstedt, T., Morth, C.M., Lychagin, M.Y., Chalov, S.R. 2017. Speciation and hydrological transport of metals in non-acidic river systems of the Lake Baikal basin: Field data and model predictions, Regional Environmental Change, 17(7), 2007-2021.
  • 24. Wallace, W.G., Estephan, A. 2004. Differential susceptibility of horizontal and vertical swimming activity to cadmium exposure in a gammaridean amphipod (Gammarus lawrencianus). Aquatic Toxicology, 69, 289–297.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-309fce08-c892-490f-94de-6a0ce761e217
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