Arsenic Uptake and Depuration by Red Swamp Crayfish, Procambarus clarkii

Year 2019, Volume: 4 Issue: 3, 332 - 337, 30.12.2019

Kenan Gedik Manoch Kongchum Ronald D. Delaune

https://doi.org/10.35229/jaes.579763

Cited By: 1

Abstract

Paddy rice soils, which can contain
elevated levels of arsenic, also have importance in crayfish production in
Louisiana (USA). In this study, arsenic accumulation and depuration in the
tissues of crayfish (Procamborus clarkii) exposed to different As
concentrations were determined. For this purpose, crayfish were exposed to 3
different concentrations of As (0,2; 0,8 and 2 mg As L^-1) for 14 days and then
kept in As free water for following 14 days. Arsenic concentrations were
determined in crayfish tissues (gill, muscle, exoskeleton, hepatopancreas) during
both the accumulation (1, 3, 7 and 14th days) and depuration (15, 17, 21, and
28th days) phases. During the accumulation period, arsenic concentration in the
tissues was found to increase proportionally with time and exposure
concentrations: gill > hepatopancreas > exoskeleton > muscle. During
this period, however, the arsenic concentration in the tissues did not reach
the equilibrium. In the depuration phase, arsenic elimination varied ranging
between 54.63-87.91% in the hepatopancreas, 42.69 to 74.21% in the gills,
35.56-73.55% in the exoskeletons and 26.75-49.84% in the muscles.

Keywords

Accumulation, bioconcentration factor, elimination, kinetic

Thanks

I thank the Council of Higher Education of Turkey for supporting Kenan Gedik. I also thank Dr. Ronald D. DeLaune and Dr. Manoch Kongchum for suggestions and comments on the manuscript.

References

• Alcorlo, P., Otero, M., Crehuet, M., Baltanas A. & Montes, C., (2006). The use of the red swamp crayfish (Procambarus clarkii, Girard) as indicator of the bioavailability of heavy metals in environmental monitoring in the River Guadiamar (SW, Spain). Science of the Total Environment, 366, 380-390.
• Anderson, MB., Reddy P., Preslan, JE., Fingerman, M., Bollinger, J., Jolibois, L., Maheshwarudu, G. & George, WJ., (1997). Metal accumulation in crayfish, Procambarus clarkii, exposed to a petroleum-contaminated Bayou in Louisiana. Ecotoxicology and Environmental Safety, 37, 267-272.
• Azizur Rahman, M. & Hasegawa, H., (2012). Arsenic in freshwater systems: Influence of eutrophication on occurrence, distribution, speciation, and bioaccumulation. Applied Geochemistry, 27, 304-314.
• Devesa, V., Súñer, MA., Lai, VWM., Granchinho, SCR Martínez, JM., Vélez, D., Cullen, WR. & Montoro, R. (2012). Determination of arsenic species in a freshwater crustacean Procambarus clarkii. Applied Organometallic Chemistry, 16, 123-132.
• EPA, 1994. Determination of Trace Elements in Waters and Wastes by Inductively Coupled Plasma Masss Pectrometry. In (pp. 57). Cincinnati, Ohio: Environmental Protection Agency, Environmental Monitoring Systems Lab.
• Gedik, K., DeLaune, RD., Kongchum, M. and Gambrell, RP. (2017a). Physicochemical factors controlling stability of toxic heavy metals and metalloids in wetland soils and sediments. In: J. Rinklebe, A.S. Knox, M.H. Paller (Eds), Trace Elements in Waterlogged Soils and Sediments, CRC Press, Baco Raton, FL.
• Gedik, K., Kongchum, M., DeLaune, RD. & Sonnier, JJ., (2017b). Distribution of arsenic and other metals in crayfish tissues (Procambarus clarkii) under different production practices. Science of the Total Environment, 574, 322-331.
• Gedik, K., Terzi, E. & Yesilcicek, T., (2018). Biomonitoring of metal(oid)s in mining-affected Borcka Dam Lake coupled with public health outcomes. Human and Ecological Risk Assessment: An International Journal, DOI: 10.1080/10807039.2018.1443390.
• Guner, U. (2010). Cadmium bioaccumulation and depuration by freshwater crayfish, Astacus leptodactylus. Ekoloji. 19, 23-28.
• IARC, 2012. A review of human carcinogens. c. metals, arsenic, fibres and dusts. WHO Press. Lyon, France.
• Knowlton, M.F., Boyle, TP. & Jones J.R., (1983). Uptake of lead from aquatic sediment by submersed macrophytes and crayfish. Archives of Environmental Contamination and Toxicology, 12, 535-541.
• LSAN, 2016. Louisiana Summary Agriculture and Natural Resources http://www.lsuagcenter.com/~/media/system/f/7/d/5/f7d55ad7acd132356d5969cb360afd51/2016%20ag%20summary_finalpdf.pdf. Accessed 20 June 2017.
• Mandal, BK. & Suzuki, KT., (2002). Arsenic round the world: a review. Talanta, 58, 201-235.
• McClain, WR., Romain, RP., Lutz, CG. and Shirley, MG. (2007). Louisiana Crawfish Production Manual. Louisiana State University Agriculture Center and Louisiana Crawfish Production Board Publication, Baton Rouge, Louisiana.
• Meharg, AA., Williams, PN., Adomako, E., Lawgali, YY. Deacon, C., Villada, A., Cambell, RC., Sun, G., Zhu, YG., Feldmann, J., Raab, A., Zhao, FJ., Islam, R., Hossain, S. & Yanai, J., (2009). Geographical variation in total and inorganic arsenic content of polished (white) rice. Environmental Science & Technology, 43, 1612-1617.
• Naqvi, SM. & Howell, RD. (1993). Toxicity of cadmium and lead to juvenile red swamp crayfish, Procambarus-clarkii, and effects on fecundity of adults. Bulletin of Environmental Contamination and Toxicology, 51, 303-308.
• Naqvi, SM., Devalraju, I. & Naqvi, NH. (1998). Copper bioaccumulation and depuration by red swamp crayfish, Procambarus clarkii. Archives of Environmental Contamination and Toxicology, 61, 65-71.
• Naqvi, SM., Flagge, CT. and Hawkins, RL. (1990). Arsenic uptake and depuration by red crayfish, Procambarus clarkii, exposed to various concentrations of monosodium methanearsonate (MSMA) herbicide. Bulletin of Environmental Contamination and Toxicology, 45, 94-100.
• Neelam, V., Hardaway, CJ., Richert, JC., Sneddon, J. (2010). A laboratory controlled study of uptake of copper, lead, and zinc in crawfish (Procambrus clarkii) by inductively coupled plasma optical emission spectrometry. Analytical Letters, 43, 1770-1779.
• OECD, 2012. Test No. 305: Bioaccumulation in Fish: Aqueous and Dietary Exposure, OECD Publishing. http://dx.doi.org/10.1787/2074577x
• Soedarini, B., Klaver, L., Roessink, I., Widianarko, B., Van Straalen, NM. & Van Gestel, CAM. (2012). Copper kinetics and internal distribution in the marbled crayfish (Procambarus sp.). Chemosphere, 87, 333-338.
• Weisbrod, AV., Burkhard, LP., Arnot,,J., Mekenyan,,O., Howard, P.H., Russom, C. & Boethling, R. (2007). Workgroup Report: Review of Fish Bioaccumulation Databases Used to Identify Persistent, Bioaccumulative, Toxic Substances. Environmental Health Perspectives, 115, 255-261.