Abstract
In risk assessment of aquatic sediments, the immobilizing effect of acid-volatile sulfide (AVS) on trace metals is a principal control on availability and associated toxicity of metals to aquatic biota, which reduces metal bioavailability and toxicity by binding and immobilizing metals as insoluble sulfides. Spatial variation pattern of AVS, simultaneously extracted metals (SEM), and sediment characteristics were studied for the first time in surface sediment samples (0–20 cm) from 43 locations in Egyptian northern delta lagoons (Manzalah, Burullus, and Maryut) as predictors of the bioavailability of some divalent metals (Cu, Zn, Cd, Pb, and Ni) in sediments as well as indicators of metal toxicity in anaerobic sediments. The results indicated that the ∑SEM (Cu + Zn + Cd + Pb + Ni) values in sediments of lagoon Burullus had higher concentrations than those of Maryut and Manzalah. In contrast, AVS concentrations were considerably higher in lagoons Manzalah and Maryut and seemed to be consistent with the increase in organic matter than lagoon Burullus. Generally, the average concentrations of the SEM in all lagoons were in the order of Zn > Cu > Ni > Pb > Cd. The ratios of ∑SEM/AVS were less than 1 at all the sampling stations except at one station in lagoon Maryut as well as four stations located in lagoon Burullus (∑SEM/AVS > 1), which suggests that the metals have toxicity potential in these sediments. Therefore, SEM concentrations probably are better indicators of the metal bioavailability in sediments than the conventional total metal concentrations.
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Ahmed, M. H., El Leithy, B. M., Thompson, J. R., Flower, R. J., Ramdani, M., Ayache, F., et al. (2009). Application of remote sensing to site characterisation and environmental change analysis of North African coastal lagoons. Hydrobiologia (2009), 622, 147–171.
Allen, H. E., Fu, G., & Deng, B. (1993). Analysis of acid-volatile sulfide (AVS) and simultaneously extracted metals (SEM) for the estimation of potential toxicity in aquatic sediments. Environmental Toxicology and Chemistry, 12, 1441–1453.
Ankley, G. T., Di Toro, D. M., & Hansen, D. J. (1996). Technical basis and proposal for deriving sediment quality criteria for metals. Environmental Toxicology and Chemistry, 15, 2056–2066.
Chapman, P. M., Wang, F. Y., Germano, J. D., & Batley, G. (2002). Pore water testing and analysis: the good, the bad, and the ugly. Marine Pollution Bulletin, 44, 359–366.
Cooper, D. C., & Morse, J. W. (1998). Extractability of metal sulfide minerals in acidic solutions: application to environmental studies of trace metal contamination within anoxic sediments. Environmental Science and Technology, 32, 1076–1078.
De Schamphelaere, K. A. C., & Janssen, C. R. (2004). Effects of dissolved organic carbon concentration and source, pH, and water hardness on chronic toxicity of copper to Daphnia magna. Environmental Toxicology and Chemistry, 23, 1115–1122.
Di Toro, D. M., Mahony, J. D., Hansen, D. J., Scott, K. J., Hicks, M. B., Mayr, S. M., et al. (1990). Toxicity of cadmium in sediments: the role of acid volatile sulfide. Environmental Toxicology and Chemistry, 9, 1487–1502.
Di Toro, D. M., Mahony, J. D., & Hansen, D. J. (1992). Acid volatile sulfide predicts the acute toxicity of cadmium and nickel in sediments. Environmental Science and Technology, 26, 96–101.
ECRI. (2002). The hydrological status of El-Manzala Lake. Environment and Climate Research Institute.
El Nemr, A. (2003). Assessment of heavy metal pollution in surface muddy sediments of Lake Burullus, southeastern Mediterranean, Egypt. Egypt J. Agual. Biol & Fish, 7(4), 67.
El-Sharkawi, & Fahmy M. (1999). Pollution control of Lake Mariout. International Conference on Environmental Management, Health and Sustainable Development, held in Alexandria, Egypt.
Fang, T., Li, X., & Zhang, G. (2005). Acid volatile sulfide and simultaneously extracted metals in the sediment cores of the Pearl River estuary, South China. Ecotoxicology and Environmental Safety, 61, 420–431.
Fedotov, P. S., & Miró, M. (2008). Fractionation and mobility of trace elements in soils and sediments. In A. Violante, P. M. Huang, & G. M. Gadd (Eds.), Biophysico-chemical processes of heavy metals and metalloids in soil environments. Wiley-Jupac series (Vol. 1, pp. 467–520). Hoboken: Wiley.
Folk, R. L. (1974). Petrology of sedimentary rocks. Austin: Hemphill.
George, M. O., William, G. B., Robyn, E. H., & Jerry, L. F. (2007). Effects of acid-volatile sulfide on metal bioavailability and toxicity to midge (Chironomus tentans) larvae in black shale sediments. Environmental Toxicology and Chemistry, 26(2), 325–334.
Hamed, M. A., & Okbah, M. A. (2006). Trace metals speciation in sediments of Lake Manzala, Egypt. Egyptian Journal Aquatic Biology & Fish, 10(3), 137–164.
Isabelle, S., & Alfonso, M. (2000). Trace metal remobilization following the resuspension of estuarine sediments: Saguenay Fjord, Canada. Applied Geochemistry, 15, 191–210.
Kuang-Chung, Y. U., Tsal, L.-J., Chen, S.-H., & Shien-Tsong, H. (2001). Chemical binding of heavy metals in anoxic river sediments. Water Research, 35(17), 4086–4094.
Long, E. R., Field, L. J., & Mac Donald, D. D. (1998). Predicting toxicity in marine sediments with numerical sediment quality guidelines. Environmental Toxicology and Chemistry, 17, 714–727.
Masoud, M. S., Fahmy, M. A., Ali, A. E., & Mohamed, E. A. (2011). Heavy metal speciation and their accumulation in sediments of Lake Burullus, Egypt. Environmental Science and Technology, 5(4), 280–298.
Morse, J. W., & Cornwell, J. C. (1987). Analysis and distribution of iron sulfide minerals in recent anoxic marine sediments. Marine Chemistry, 22, 55–69.
Morse, J. W., & Rickard, D. (2004). Chemical dynamics of sedimentary acid volatile sulfide. Environmental Science Technology, 38, 131A–136A.
Nizoli, E. C., & Luiz-Silva, W. (2012). Seasonal AVS–SEM relationship in sediments and potential bioavailability of metals in industrialized estuary, southeastern Brazil. Environmental Geochemistry and Health, 34, 263–272.
Okbah, M.A., Aboel-khair, E.M., Moustafa. H.M. (2006). Simultaneously extracted metals/acid volatile sulfide in surface sediments from Damietta port and the offshore area. EJAR, ISSN: 1687–4285
Parker, J. C. (1983). A comparison of methods used for measurement of organic matter in sediments. Chemistry and Ecology, 1, 201–210.
Peng, S. H., Wang, W. X., Li, X., & Yen, Y. F. (2004). Metal partitioning in river sediments measured by sequential extraction and biomimetic approaches. Chemosphere, 57, 839–851.
Rickard, D., & Morse, J. W. (2005). Acid volatile sulfide (AVS). Marine Chemistry, 97, 141–197.
Saad, M.A.H., and Safty, A.M., (2004). Environmental problems in two Egyptian shallow lakes subjected to different levels of pollution. Eighth International Water Technology Conference, Alexandria, Egypt.
Saeed S. M. and Shaker I. M. (2008). Assessment of heavy metals pollution in water and sediments and their effect on Oreochromis niloticus in the northern delta lakes, Egypt. 8th International Symposium on Tilapia in Aquaculture. pp, 475–489.
Stumm, W., & Morgan, J. J. (1981). Aquatic chemistry—an introduction emphasizing chemical equilibria in natural waters. New York: Wiley.
Swartz, R. C., Ditsworth, G. R., Schults, D. W., & Lamberson, J. O. (1985). Sediment toxicity to a marine infaunal amphipod: cadmium and its interaction with sewage sludge. Marine Environment Research, 18, 133–153.
Tao Fanga, B., Xiangdong, L., & Zhangc, G. (2005). Acid volatile sulfide and simultaneously extracted metals in the sediment cores of the Pearl River estuary, South China. Ecotoxicology and Environmental Safety, 61, 420–431.
U.S. Environmental Protection Agency. (1994). Equilibrium partitioning approach to predicting metal bioavailability in sediments and the derivation of sediment quality criteria for metals, Vol. 1-briefing report to the Science Advisory Board. EPA 822-D-94-002. Office of Water, Office of Research and Development, Washington, DC.
U.S. Environmental Protection Agency. (2001). Methods for collection, storage, and manipulation of sediments for chemical and toxicological analyses: technical manual (EPA-823-N-01-002). Washington, DC: Office of Water.
U.S. Environmental Protection Agency. (2005). Procedures for the derivation of equilibrium partitioning sediment benchmarks (ESBs) for the protection of benthic organisms: metal mixtures (cadmium, copper, lead, nickel, silver, zinc) (EPA/600/R-02/011). Washington, DC: Office of Research and Development.
Van den Berg, G. A., Loch, J. P. G., Van der Heijdt, L. M., & Zwolsman, J. J. G. (1998). Vertical distribution of acid-volatile sulfide and simultaneously extracted metals in a recent sedimentation area of the river Meuse in the Netherlands. Environmental Toxicology and Chemistry, 17, 758–763.
Van den Hoop, M. A. G. T., Den Hollander, H. A., & Kerdijk, H. N. (1997). Spatial and seasonal variations of acid volatile sulphide (AVS) and simultaneously extracted metals (SEM) in Dutch marine and freshwater sediments’. Chemosphere, 35, 2307–2316.
Van Griethuysen, C., Meijboom, E. W., & Koelmans, A. A. (2003). Spatial variation of metals and acid-volatile sulfide in floodplain lake sediment. Environmental Toxicology and Chemistry, 22, 457–465.
Van Griethuysen, C., de Lange, H. J., van den Heuij, M., de Bies, S. C., Gillissen, F., & Koelmans, A. A. (2006). Temporal dynamics of AVS and SEM in sediment of shallow freshwater floodplain lakes. Applied Geochemistry, 21, 632–642.
Younis, A. M., & Nafea, E. M. (2012). Impact of environmental conditions on the biodiversity of Mediterranean Sea lagoon, Burullus protected area, Egypt. World Applied Sciences Journal, 19(10), 1423–1430.
Yu, K. C., TsaI, L. J., Chen, S. H., & Ho, S. T. (2001). Chemical binding of heavy metals in anoxic river sediments. Water Research, 17, 4086–4094.
Acknowledgments
The authors are grateful to Environmental Monitoring Programme and Dr. Mamdouh A. Fahmy, Marine Chemistry Lab., National Institute of Oceanography and Fisheries for the support and for providing the samples used in this research.
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Younis, A.M., El-Zokm, G.M. & Okbah, M.A. Spatial variation of acid-volatile sulfide and simultaneously extracted metals in Egyptian Mediterranean Sea lagoon sediments. Environ Monit Assess 186, 3567–3579 (2014). https://doi.org/10.1007/s10661-014-3639-3
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DOI: https://doi.org/10.1007/s10661-014-3639-3