【 摘 要 】

Background and aim

Mediterranean Sea, Egypt is an economically important marine environment. During the last decades there has been extensive increase in the levels of urbanization and industrialization along its coastal area. Therefore, the present work attempts to determine the status of heavy metals distribution in sediment samples, and their ecological risk assessment in the studied area.

Materials and methods

Twenty surfacial sediment samples were collected from different selected stations along the Egyptian Mediterranean Sea. The samples were homogenized and placed into sealed polyethylene bags, carried to the laboratory in an ice box and stored at −20 °C in the dark until analysis.

Results

The results revealed that Fe had the highest mean value (243–38045 μgg ⁻¹ ) followed by Mn (17–1086 μgg ⁻¹ ), and a lower concentrations were found for Co (0.43–26.39 μgg ⁻¹ ) and Cd (0.04–0.47 μgg ⁻¹ ). Risk assessment showed that Cd had the highest ecological risk (Er = 21.52), followed by Pb (Er = 3.01), while Zn had the lowest risk (Er = 0.23). Both the ecotoxicological index method and the potential ecological risk index (RI) suggested that the combined ecological risk of the studied metals may be low. Multivariate statistical analysis (Cluster and Factor analysis) suggested that the lithogenic factor dominants the distribution of most part of the considered metals in the study area.

Conclusion

Multivariate analysis has been proved to be an effective tool for providing suggestive information regarding heavy metal sources and pathways. The results of this study provide valuable information about metal contamination in sediments along the Mediterranean Sea for over than 1200 km.

【 授权许可】

   
2015 Soliman et al.

【 预 览 】

附件列表

Files	Size	Format	View
20151022092040502.pdf	1261KB	PDF	download
Fig. 6.	16KB	Image	download
Fig. 5.	19KB	Image	download
Fig. 4.	10KB	Image	download
Fig. 3.	37KB	Image	download
Fig. 2.	56KB	Image	download
Fig. 1.	30KB	Image	download

【 图 表 】

【 参考文献 】

• [1]Dabaradaran S, Naddafi K, Nazmara S, Ghaedi H. Heavy metals (Cd, Cu, Ni and Pb) content in two fish species of Persian Gulf in Bushehr Port. Iran Afr J Biotechnol. 2010; 37:6191-3.
• [2]Jain CK, Gupta H, Chakrapani GJ. Enrichment and fractionation of heavy metals in bed sediments of river Narmada. India Environ Monit Assess. 2008; 141:35-47.
• [3]Bai JH, Cui BS, Chen B, Zhang KJ, Deng W, Gao HF, Xiao R. Spatial distribution and ecological risk assessment of heavy metals in surface sediments from a typical plateau lake wetland. China Ecol Modell. 2011; 222:301-6.
• [4]Hogstand C, Haux C. Binding and detoxification of heavy metals in lower vertebrates with reference to metallothionein. Comp Biochem Physiol C. 2011; 100:137-214.
• [5]Damek-Proprawa M, Sawicka-Kapusta K. Damage to the liver, kidney and testes with reference to burden of heavy metals in yellow-necked mice from areas around steel workers and zinc smelters in Poland. Toxicology. 2003; 186:1-10.
• [6]EC, 2001. Commission Regulation (EC) No. 466/2001 of 8 March 2001. Official Journal of European Communities 1.77/1
• [7]Guidelines Document for cadmium in shellfish. US. Department of Health and Human Services, Public Health Service Office, Office of Seafood(HFS-416), Washington, DC; 1993.
• [8]Malferrari D, Brigatti MF, Laurora A, Pini S. Heavy metals in sediments from canals for water supplying and drainage; mobilization and control strategies. J Hazard Mater. 2009; 161:723-9.
• [9]Chen TR, Yu KF, Li Price GJ, Chi Q, Wei GJ. Heavy metal pollution recorded in Porites corals from Daya Bay, northern South China Sea. Mar Environ Res. 2010; 70:318-26.
• [10]Simpson SL, Batley GE, Chariton AA, Stauber JL, King CK, Chapman JC, Hyne RV, Gale SA, Roach AC, Maher WA. Handbook for sediment quality assessment. CSIRO, Bangor; 2005.
• [11]Hakanson L. An ecological risk index for aquatic pollution control. A sedimentological approach. Water Res. 1980; 14:975-1001.
• [12]Yang Z, Wang Y, Shen Z, Niu J, Tang Z. Distribution and speciation of heavy metals from the mainstream, tributaries, and lakes of the Yangtz River catchment of Wuhan. China J Hazard Mater. 2009; 166:1186-94.
• [13]Long ER, MacDonald DD, Seven CG, Hong CB. Classifying the probabilities of acute toxicity in marine sediments with empirically derived sediment quality guidelines. Environ Toxicol Chem. 2000; 19:2598-601.
• [14]Emam W, Saad AA, El-Moselhy KM, Owen NA. Evaluation of water quality of Abu Qir Bay, Mediterranean coast, Egypt. IJESE. 2013; 4:47-54.
• [15]Dowidar NM. Productivity of the south-eastern Mediterranean. In: Natural and Man-Made Hazards. El-Sabh MI, Murty TS, editors. Reidel Publishing Company, Dordrecht; 1988: p.477-98.
• [16]Okbah MA, Nasr SM, Soliman NF, Khairy MA. Distribution and contamination status of trace metals in the Mediterranean coastal sediments, Egypt. Soil Sediment Contam. 2014; 23:656-76.
• [17]Guidelines for Municipal Solid Waste Management: Planning in Small Islands Developing States in the Pacific Region, South Pacific Regional Environment Programme (SPREP). Apia, Western Samoa; 1999.
• [18]El-Nemr AM, Sikaily AE, Khaled A. Total and leachable heavy metals in muddy and sandy sediments of Egyptian coast along Mediterranean Sea. Environ Monit Assess. 2007; 129:151-68.
• [19]Khaled A, El Nemr A, El Sikaily A, El-Sarraf WM. Assessment of heavy metals in the sediments of the Mediterranean coast of Egypt. EJAR. 2010; 36:43-53.
• [20]Nasr SM, Khairy MA, Okbah MA, Soliman NF. AVS-SEM Relationships and Potential Bioavailability of Trace Metals in Sediments from the Southeastern Mediterranean Sea, Egypt. Chem Ecol. 2014; 30:15-28.
• [21]Nasr SM, Soliman NF, Khairy MA, Okbah MA. Metals Bioavailability in Surface Sediments off Nile Delta, Egypt: Application of Acid Leachable Metals and Sequential Extraction Techniques. Environ Monit Assess. 2015; 187:312.
• [22]Oregioni B, Aston SR. Determination of selected trace metals in marine sediments by flame/flameless atomic absorption spectrophotometer. IAEA Monaco Laboratory Internal Report. Now cited in reference method in pollution studies No. 38, UNEP; 1984.
• [23]Yan C, Li O, Zhang X, Li G. Mobility and ecological risk assessment of heavy metals in surface sediments of Xiamen Bay and its adjacent areas. China Environ Earth Sci. 2010; 60:1469-79.
• [24]Baruah TC, Barthakur HP. A textbook of soil analysis. Vikas Publishing House, Pvt. Ltd, New Delhi, India; 1997.
• [25]Black CA. Methods of soil analysis, part 2, Chemical and Microbiological properties. American society of Agronomy Inc., Madison, Wisc; 1965.
• [26]Folk RL, Ward WC. Brazos river bar: a study in the significance of grain size parameters. J Sed Petrol. 1957; 27:3-32.
• [27]McCready S, Birch GF, Long ER. Metallic and organic contaminants in sediments of Sydney Harbour, Australia and vicinity-a chemical dataset for evaluating sediment quality guidelines. Environ Int. 2006; 32:455-65.
• [28]Dias De Alba M, Galindo-Riano MD, Casanuueva-Marenco MJ, Garcia-Vargas M, Kosore CM. Assessment of the metal pollution, potential toxicity and speciation of sediment from Algeciras Bay (South of Spain) using chemometric tools. J Hazard Mater. 2011; 190:177-87.
• [29]Marine Sediment Quality (GB 18668–2002). Standards Press of China, Beijing; 2002.
• [30]Marine water quality in Hong Kong. Environment Protection department, Hong Kong Government Printer, Hong Kong; 1992.
• [31]Long ER, McDonald D, Smith SL, Calder FD. Incidence of adverse biological effects within ranges of chemical concentrations in marine and estuarine sediments. Environ Manage. 1995; 19:81-97.
• [32]Saleem M, Iqbal J, Shah MH. Study of seasonal variations and risk assessment of selected metals in sediments from Mangla Lake, Pakistan. J Geochem Explor. 2012; 125:144-52.
• [33]Gao X, Li P. Concentration and fractionation of trace metals in surface sediments of intertidal Bohai Bay, China. Mar Pollut Bull. 2012; 64:1529-36.
• [34]Anders B, Reischmann T, Poller U, Kostopoulos D. Age and origin of granitic rocks of the eastern Vardar Zone, Greece: new constraints on the evolution of the Internal Hellenides. J Geol Soc. 2005; 162:857-70.
• [35]Chapman PM, Mann GS. Sediment quality values (SQVs) and ecological risk assessment. Mar Pollut Bull. 1999; 38:339-44.
• [36]Rahman MS, Saha N, Molla AH. Potential ecological risk assessment of heavy metal contamination in sediment and water body around Dhaka export processing zone, Bangladesh. Environ. Earth Sci. 2013; DOI 10.1007/s12665-013-26315
• [37]Qui H. Studies on the potential ecological risk and homology correlation of heavy metal in the surface soil. JAS. 2010; 2:194-201.
• [38]Xu ZQ, Ni SJ, Tuo XG. Calculation of heavy metals toxicity coefficient in the evaluation of potential ecological risk index. Environ Sci Tech. 2008; 31:112-5.
• [39]Turekian KK, Wedepohl KH. Distribution of the elements in some major units of the earth’s crust. Bull Geol Soc America. 1961; 72:175-92.
• [40]Taylor SR. Abundance of chemical elements in the continental crust: a new table. Geochim Cosmochim Ac. 1972; 28:1273-85.
• [41]Uluturhan E, Kontas A, Can E. Sediments concentrations of heavy metals in the Homa Lagoon (Eastern Agean Sea): Assessment of contamination and ecological risks. Mar Pollut Bull. 2011; 62:1989-97.
• [42]Bhuiyan MA, Parver L, Isalm MA, Dampare SB, Suzuki S. Heavy metal pollution of coal mine affected agricultural soils in the northern part of Bangladesh. J Hazard Mater. 2009; 173:384-92.
• [43]Farkas A, Erratico C, Vigano L. Assessment of the environmental significance of heavy metal pollution in surficial sediments of the River Po. Chemosphere. 2007; 68:761-8.
• [44]Pedersen F, Bjørnestad E, Andersen HV, Kjølholt J, Poll C. Characterization of sediments from Copenhagen Harbour by use of biotests. Water Sci Technol. 1998; 37:233-40.
• [45]Hu D, He J, Lu C, Ren L, Fan Q, Wang J, Xie Z. Distribution characteristics and potential ecological risk assessment of heavy metals (Cu, Pb, Zn, Cd) in water and sediments from Lake Dalinouer, China. Ecotoxol Environ Saf. 2013; 93:135-44.
• [46]Krishna AK, Mohan KR, Murthy NN. Multivariate statistical approach for Monitoring of heavy metals in sediments: A case study from Wailpalli Watershed, Nalgonada district, Andhra Pradesh, India. Res J Environ Earth Sci. 2011; 3:103-13.
• [47]Alonso Castillo ML, Sánchez Trujillo I, Vereda Alonso E, García de Torres A, Cano Pavón JM. Bioavailability of heavy metals in water and sediments from a typical Mediterranean Bay (Málaga Bay, Region of Andalucía, Southern Spain). Mar Pollut Bull. 2013; 76:427-34.
• [48]Omar MB, Mendiguchıa C, Er-Raioui H, Marhraoui M, Lafraoui G, Oulad-Abdellah MK, et al. Distribution of heavy metals in marine sediments of Tetouan coast (North of Morocco): natural and anthropogenic sources. Environ. Earth Sci. 2015; DOI 10.1007/s12665-015-4494-4
• [49]Neser G, Kontas A, Unsalan D, Uluturhan E, Altay O, Darılmaz E, Kucuksezgin F, Tekogul N, Yercan F. Heavy metals contamination levels at the Coast of Aliaga (Turkey) ship recycling zone. Mar Pollut Bull. 2012; 64:882-7.
• [50]Hartmann G, Wedepohl KH. The composition of peridotite tectonites from the Ivrea Complex, northern Italy: residues from melt extraction. Geochim Cosmochim Ac. 1993; 57:1761-82.
• [51]Nasr SM, Okbah MA, El Haddad HS, Soliman NF. Assessment of metals contamination in sediments from the Mediterranean Sea (Libya) using pollution indices and multivariate statistical analysis. GJAR. 2015; 2:120-36.
• [52]Kaiser MF, Aboulela HA, El-Serehy HA, Ezz El-Din H. Heavy metals contamination of a Mediterranean coastal ecosystem, eastern Nile delta, Egypt. In: Dr. Stephen Young, editor. International perspectives on global environmental change. ISBN: 978-953-307-815-1, InTech; 2012.