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Metal concentrations in waters, sediments and biota of the far south-east coast of New South Wales, Australia, with an emphasis on Sn, Cu and Zn used as marine antifoulant agents

  • I. R. McVay
  • W. A. Maher
  • F. Krikowa
  • R. Ubrhien
Original Paper

Abstract

Tin, Cu, Zn, Cd, Pb, Ag and Hg concentrations were measured in waters, sediments and three ubiquitous sedentary molluscs: the oyster, Saccostrea glomerata, a rocky intertidal gastropod, Austrocochlea porcata, and a sediment-dwelling gastropod, Batillaria australis, at 12 locations along the far south coast of NSW, Australia, from Batemans Bay to Twofold Bay during 2009. Metal concentrations in water for Sn, Cd, Ag and Hg were below detection limits (< 0.005 μg/L). Measurable water metal concentrations were Cu: 0.01–0.08 μg/L, Zn: 0.005–0.11 μg/L and Pb: 0.005–0.06 μg/L. Mean metal concentration in sediments were Sn < 0.01–2 μg/g, Cu < 0.01–605 μg/g, Zn 23–765 μg/g, Cd < 0.01–0.5 μg/g, Pb < 0.01–0.3 μg/g, Ag < 0.01–0.9 μg/g and Hg < 0.01–2.3 μg/g. Several locations exceeded the Australian and New Zealand Environment and Conservation Council and Agriculture and Resource Management Council of Australia and New Zealand (Australian and New Zealand guidelines for fresh and marine water quality 2000) low and high interim sediment quality guidelines’ levels for Cu, Zn, Cd and Hg. Some sites had measurable Sn concentrations, but these were all well below the levels of tributyltin known to cause harm to marine animals. Elevated metal concentrations are likely to be from the use of antifoulants on boats, historical mining activities and agriculture in the catchments of estuaries. All molluscs had no measurable concentrations of Sn (< 0.01 μg/g) and low mean Ag (< 0.01–1.5 μg/g) and Hg (< 0.01–0.5 μg/g) concentrations. Mean Cu (24–1516 μg/g), Zn (45–4644 μg/g), Cd (0.05–5μg/g) and Pb (0.05–1.1 μg/g) in oysters were close to background concentrations. Oysters have Cd and Pb concentrations well below the Australian Food Standards Code (2002).] There were no significant correlations between metal concentrations in sediments and in organisms within locations, and no relationship with levels of boating activity and suspected antifouling contamination. Although not pristine, the low levels of metal contamination in sediments and molluscs in comparison with known metal-contaminated areas indicate that this region is not grossly contaminated with metals and suitable for the development of mariculture.]

Keywords

Metals Sediments Biota NSW South coast Australia 

Supplementary material

10653_2018_215_MOESM1_ESM.doc (360 kb)
Supplementary material 1 (DOC 359 kb)
10653_2018_215_MOESM2_ESM.docx (1.8 mb)
Supplementary material 2 (DOCX 1805 kb)

References

  1. ANFA. (2002). Australian food standards code. Melbourne: Australia New Zealand Food Authority.Google Scholar
  2. ANZECC/ARMCANZ. (2000). Australian and New Zealand guidelines for fresh and marine water quality. Melbourne: Australian and New Zealand Environment and Conservation Council and Agriculture and Resource Management Council of Australia and New Zealand.Google Scholar
  3. Apte, S. C., Batley, G. E., Szymczak, R., Rendell, P. S., Lee, R., & Waite, T. D. (1998). Baseline metal concentrations in New South Wales coastal waters. Marine & Freshwater Research, 49, 201–214.CrossRefGoogle Scholar
  4. Baldwin, S., Deaker, M., & Maher, W. (1994). Low-volume microwave digestion of marine biological tissues for the measurement of trace elements. Analyst, 119, 1701–1704.CrossRefGoogle Scholar
  5. Bao, V. W., Leung, K. M., Kwok, K. W., Zhang, A. Q., & Lui, G. C. (2008). Synergistic toxic effects of zinc pyrithione and copper to three marine species: Implications on setting appropriate water quality criteria. Marine Pollution Bulletin, 57, 616–623.CrossRefGoogle Scholar
  6. Batley, G. E., Brockbank, C. I., & Scammel, M. S. (1992). The impact of banning of tributyltin based anti-fouling paints on the Sydney rock oyster, Saccostrea commercialis. Science of the Total Environment, 122, 301–314.CrossRefGoogle Scholar
  7. Bega Valley and Eurobodalla Shire Council. (2000). Wallaga lake estuary management plan (no. 5, pp. 1–57).Google Scholar
  8. Bighiu, M. A., Eriksson-Wiklundi, A.-K., & Eklundi, B. (2017). Biofouling of leisure boats as a source of metal pollution. Environmental Science and Pollution Research, 24, 997–1006.CrossRefGoogle Scholar
  9. Boxall, A. B. A., Comber, S. D., Conrad, A. U., Howcroft, J., & Zaman, N. (2000). Modelling of Antifouling Biocides in UK Estuaries. Marine Pollution Bulletin, 40, 898–905.CrossRefGoogle Scholar
  10. Boyle, E. A., Edmond, J. M., & Sholkovitz, E. R. (1977). The mechanism of iron removal in estuaries. Geochimica et Cosmochimica Acta, 41, 1313–1324.CrossRefGoogle Scholar
  11. Chandrika, V., Tarit, C., & Kunal, G. (1997). Complexation of humic substances with oxides of iron and aluminium. Soil Science, 162, 28–34.CrossRefGoogle Scholar
  12. Clarke, K. R., & Warwick, R. M. (1994). Changes in marine communities: An approach to statistical analysis and interpretation. Plymouth: Plymouth Marine Laboratory.Google Scholar
  13. Comber, S. D. W., Franklin, G., Gardner, M. J., Watts, C. D., Boxall, A. B. A., & Howcroft, J. (2002). Partitioning of marine antifoulants in the marine Environment. The Science of the Total Environment, 286, 61–71.CrossRefGoogle Scholar
  14. Comber, S. D. W., Gunn, A. M., & Whalley, C. (1995). Comparison of the partitioning of trace metals in the Humber and Mersey estuaries. Marine Pollution Bulletin, 30, 851–860.CrossRefGoogle Scholar
  15. DIST/DIRD. (2017). Regional jobs and investment packages. South Coast region of New South Wales local Investment plan. Department of Industry, Innovation and Science-Department of Infrastructure and regional development, May 2017, pp. 1–36.Google Scholar
  16. Douzva, B., Lhotka, M., Grygar, T., Machovic, V., & Herzogova, L. (2011). Insitu co-adsorption of arsenic and iron/manganese ions on raw clays. Applied Clay Science, 54, 166–171.CrossRefGoogle Scholar
  17. Edge, K. J., Daffon, K. A., Simpson, S. L., Ringwood, A. H., & Johnston, E. L. (2015). Resuspended contaminated sediments cause sub-lethal stress to oysters: a biomarker differentiates TSS and contaminant effects. Environmental Toxicology and Chemistry, 34, 1345–1353.CrossRefGoogle Scholar
  18. Fabris, G. J., & Monahan, C. A. (1995). Characterisation of toxicants in Port Phillip Bay: Metals. Technical Report No 18, Commonwealth Scientific and Industrial Research Organisation INRE Port Phillip Bay Environmental Study, Melbourne, p. 48.Google Scholar
  19. Fauser, P., Sanderson, H., Hedegaard, R. V., Sloth, J. J., Larsen, M. M., Krongaard, T., et al. (2013). Occurrence and sorption properties of arsenicals in marine sediments. Environmental Monitoring and Assessment, 185, 4679–4691.CrossRefGoogle Scholar
  20. Gay, D., & Maher, W. A. (2003). Natural variation of copper, zinc, cadmium and selenium concentrations in Bembicium namum and their potential use as a biomonitor of trace metals. Water Research, 37, 2173–2185.CrossRefGoogle Scholar
  21. Georges, A., (2002). Biometry: Statistics for ecology and natural resource management. Workbook 1: Introduction to SAS for windows (version 8). Flexible Delivery Development Unit, Centre for the Enhancement of Learning, Teaching and Scholarship (CELTS), University of Canberra, ACT 2601, Australia (IBSN: 1 740880269).Google Scholar
  22. Geosciences Australia. (2000). Lachlan fold belt project (19912000). Viewed 17 January, 2010. http://www.ga.gov.au/minerals/research/archive/lachlan_fold_belt.jsp#1-250000.
  23. Gibson, C. P., & Wilson, S. P. (2003). ‘Imposex” still evident in eastern Australia 10 years after tributyltin restrictions. Marine Environmental Research, 55, 101–112.CrossRefGoogle Scholar
  24. Guardiola, F. A., Cuesta, A., Meseguer, J., & Esteban, M. A. (2012). Risks of using antifouling biocides in aquaculture. International Journal of Molecular Science, 13, 1541–1560.CrossRefGoogle Scholar
  25. Guo, T., DeLaune, R. D., & Patrick, W. H., Jr. (1997). The influence of sediment redox chemistry on chemically active forms of arsenic, cadmium, chromium, and zinc in estuarine sediment. Environment International, 23(3), 305–316.CrossRefGoogle Scholar
  26. Hatje, V., Apte, S. C., Hales, L. T., & Birch, G. F. (2003). Dissolved trace metal distributions in Port Jackson estuary (Sydney Harbour), Australia. Marine Pollution Bulletin, 46, 719–730.CrossRefGoogle Scholar
  27. Haynes, D., & Loong, D. (2002). Antifoulant (butyltin and copper) concentrations in sediments from the Great Barrier Reef world heritage area, Australia. Environmental Pollution, 120, 391–396.CrossRefGoogle Scholar
  28. Huang, G., Bai, Z., Dai, S., & Xie, Q. (2004). Accumulation and toxic effect of organometallic compounds on algae. Applied Organometallic Chemistry, 7, 373–380.CrossRefGoogle Scholar
  29. IMO (International Maritime Organization). (2001). International convention on the control of harmful anti-fouling systems on ships, 2001. In International conference on the control of harmful anti-fouling systems for ships.Google Scholar
  30. Jardin, T., & Bunn, S. (2010). Northern Australia, whither the mercury? Marine & Freshwater Research, 61, 451–463.CrossRefGoogle Scholar
  31. Johnston, E. L., Marizinelli, E. M., Wood, C. A., Speranza, D., & Bishop, J. D. D. (2011). Bearing the burden of boat harbours: Heavy contaminant and fouling loads in a native habitat-forming alga. Marine Pollution Bulletin, 62, 2137–2144.CrossRefGoogle Scholar
  32. Johnston, E., & Roberts, D. (2009). Contaminants reduce the richness and evenness of marine communities: A review and meta-analysis. Environmental Pollution, 157, 1745–1752.CrossRefGoogle Scholar
  33. Jones, B. G., Killian, H. E., Chenhall, B. E., & Sloss, C. R. (2003). Anthropogenic effects in a coastal lagoon: Geochemical characterisation of Burrill Lake, NSW, Australia. Journal of Coastal Research, 19, 621–632.Google Scholar
  34. Jones, D. E., & Turner, A. (2010). Bioaccessibility and mobilisation of copper and zinc in estuarine sediment contaminated by antifouling paint particles. Estuarine, Coastal and Shelf Science, 8, 399–404.CrossRefGoogle Scholar
  35. Koutsaftis, A., & Aoyama, I. (2006). The interactive effects of binary mixtures of three antifouling biocides and three heavy metals against the marine algae Chaetoceros gracilis. Environmental Toxicology, 21, 432–439.CrossRefGoogle Scholar
  36. Liston, P., & Maher, W. A. (1986). Trace metal export in urban runoff and its biological significance. Bulletin of Environmental Contamination and Toxicology, 36, 900–905.CrossRefGoogle Scholar
  37. Lobel, P. B., Mogie, P., Wright, D. A., & Wu, B. L. (1982). Gonadal and non-gonadal zinc concentrations in mussels. Marine Pollution Bulletin, 13, 320–332.CrossRefGoogle Scholar
  38. Lobel, P. B., & Wright, D. A. (1982). Metal accumulation in four molluscs. Marine Pollution Bulletin, 13, 170–174.CrossRefGoogle Scholar
  39. Mackey, N. J., Williams, R. J., Kacprzac, J. L., Kazacos, M. N., Collins, A. J., & Auty, E. H. (1975). Heavy metals in cultivated oysters (Crassostrea commercialis = Saccostrea cucullata) from the estuaries of New South Wales. Australian Journal of Marine and Freshwater Research, 26, 31–46.CrossRefGoogle Scholar
  40. Maher, W., Forstner, S., Krikowa, F., Snitch, P., Chapple, G., & Craig, P. (2001). Measurement of trace metals and phosphorus in marine animal and plant tissues by low volume microwave digestion and ICPMS. Journal of Analytical Atomic Spectrometry, 22, 361–369.Google Scholar
  41. Maher, W., Krikowa, F., Kirby, J., Townsend, A. T., & Snitch, P. (2003). Measurement of trace elements in marine environmental samples using solution ICPMS. Current and future applications. Australian Journal of Chemistry, 56, 103–116.CrossRefGoogle Scholar
  42. Maher, W. A., Maher, N., Taylor, A., Krikowa, F., Ubrihien, R., & Milac, K. M. (2016). The use of the marine gastropod, Cellana tramoserica as a biomonitor of metal contamination in near shore Environments. Environmental Monitoring and Assessment, 188, 391–406.CrossRefGoogle Scholar
  43. Matthiessen, P., & Gibbs, P. E. (1998). Critical appraisal of the evidence for tributyltin-mediated endocrine disruption in mollusks. Environmental Toxicology and Chemistry, 17, 37–43.CrossRefGoogle Scholar
  44. Matthiessen, P., Reed, J., & Johnson, M. (1999). Sources and potential effects of copper and zinc concentrations in the estuarine waters of Essex and Suffolk, United Kingdom. Marine Pollution Bulletin, 38, 908–920.CrossRefGoogle Scholar
  45. McAllister, T. L., Overton, M. F., & Brill, E. D., Jr. (1996). Cumulative impact of marinas on estuarine water quality. Environmental Management, 20, 385–396.CrossRefGoogle Scholar
  46. McCall, P. L., & Tevesz, M. J. S. (Eds.). (1982). Chapter 3. The effects of Benthos on physical properties of freshwater sediments. In Animal-sediment relationsThe biogenic alteration of sediments. Topics in Geobiology (Vol. 100, pp. 105–176). New York: Springer.Google Scholar
  47. McCready, S., Birch, G. F., & Long, E. R. (2006). Metallic and organic contaminants in sediments of Sidney Harbour, Australia and vicinity: A chemical dataset for evaluating sediment quality guidelines. Environmental International, 32, 455–465.CrossRefGoogle Scholar
  48. McPherson, T. N., Burian, S. J., Stenstrom, M. K., Turin, H. J., Brown, M. J., & Suffet, I. H. (2005). Trace metal pollutant load in urban runoff from Southern California watershed. Journal of Environmental Engineering, 131, 1073–1080.CrossRefGoogle Scholar
  49. Meadows, P. S., & Tait, J. (1989). Modification of sediment permeability and shear strength by two burrowing invertebrates. Marine Biology, 101, 75–82.CrossRefGoogle Scholar
  50. Mikac, K. M., Maher, W. A., & Jones, A. R. (2007). Do physicochemical sediment variables and their soft sediment macrofauna differ among micro size coastal lagoons with forested and urban catchments? Estuarine and Coastal Shelf Science, 72, 308–318.CrossRefGoogle Scholar
  51. Munksgaard, N. C., & Parry, D. L. (2001). Trace metals, arsenic and lead isotopes in dissolved and particulate phases of North Australian coastal and estuarine seawater. Marine Chemistry, 75, 165–184.CrossRefGoogle Scholar
  52. Natural Heritage Trust. (2004). Tributyltin (TBT) analysis protocol development and current contamination assessment. A report from Natural Heritage Trust (Coasts and Clean Seas) Project No 25425 December 2004, Canberra.Google Scholar
  53. Oades, J. M. (1988). The retention of organic matter in soils. Biogeochemistry, 5, 35–70.CrossRefGoogle Scholar
  54. Oberdorster, E., & McClellan-Green, P. (2002). Mechanisms of imposex induction in the mud snail, Ilyanassa obsoleta: TBT as a neurotoxin and aromatase inhibitor. Marine Environmental Research, 54, 715–718.CrossRefGoogle Scholar
  55. Packham, D., Tapper, N., Griepsma, D., Friedli, H., Hellings, J., & Harris, S. (2009). Release of mercury in the Australian environment by burning: A preliminary investigation of biomatter and soils. Air Quality and Climate Change, 43, 24–27.Google Scholar
  56. Phillips, D. J. H. (1977). The use of biological indicator organisms to monitor metal pollution in marine and estuarine environments-a review. Environmental Pollution, 13, 281–311.CrossRefGoogle Scholar
  57. Pipe, R. K., Coles, A., Carissan, F. M. M., & Ramanathan, K. (1999). Copper induced immunomodulation in the marine mussel, Mytilus edulis. Aquatic Toxicology, 46, 43–54.CrossRefGoogle Scholar
  58. Rhoads, D. C., & Boyer, L. F. (1982). The effects of marine benthos on physical properties of sediments: A successional perspective. In P. L. McCall & M. J. S. Tevesz (Eds.), Animal-sediment relations. New York: Plenum Press.Google Scholar
  59. Robinson, W. A., Maher, W. A., Krikowa, F., Nell, J. A., & Hand, R. (2005). The use of the oyster Saccostrea glomerata as a biomonitor of metal contamination: Intra-sample, local scale and temporal variability and its implications for biomonitoring. Journal of Environmental Monitoring, 7, 208–223.CrossRefGoogle Scholar
  60. Sanudo-Wilhelmy, S. A., & Flegalt, A. R. (1992). Anthropogenic silver in the Southern California Bight: A new tracer of sewage in coastal waters. Environmental Science and Technology, 26, 2147–2151.CrossRefGoogle Scholar
  61. Scanes, P. R., & Roach, A. C. (1999). Determining natural ‘background’ concentrations of metals in oysters from New South Wales, Australia. Environmental Pollution, 105, 437–446.CrossRefGoogle Scholar
  62. Showalter, S., & Savarese, J. (2004). Restrictions on the use of marine antifouling paints containing tributyltin and copper. CA: California Sea Grant Extension Program.Google Scholar
  63. Sim, V. X. Y., Dafforn, K. A., Simpson, S. L., Kelaher, B. P., & Johnston, E. L. (2015). Sediment contaminants and infauna associated with recreational boating structures in a multi-use marine park. PLoS ONE, 10, 1–15.Google Scholar
  64. Singh, N., & Turner, A. (2009). Metals in antifouling paint particles and their heterogeneous contamination of coastal sediments. Marine Pollution Bulletin, 58, 559–564.CrossRefGoogle Scholar
  65. Smith, P. J., & McVeagh, M. (1991). Widespread organotin pollution in New Zealand coastal waters as indicated by imposex in dogwhelks. Marine Pollution Bulletin, 22, 409–413.CrossRefGoogle Scholar
  66. Spooner, D., Maher, W., & Otway, N. (2003). Metal concentrations in sediments and oysters of Botany Bay, Australia. Archives of Environmental Contamination and Toxicology, 45, 92–101.CrossRefGoogle Scholar
  67. Tanabe, S. (1999). Butyltin contamination in marine mammals: A Review. Marine Pollution Bulletin, 39, 62–72.CrossRefGoogle Scholar
  68. Taylor, A., & Maher, W. (2003). The use of two marine gastropods, Austrocochlea constricta and Bembicium auratum as biomonitors of zinc, cadmium and copper exposure: Effects of mass, within and between site variability and net accumulation relative to environmental exposure. Journal of Coastal Research Progress Series, 19, 541–549.Google Scholar
  69. Telford, K., Maher, W., Krikowa, F., & Foster, S. (2008). Measurement of total antimony and antimony species in mine contaminated soils by ICPMS and HPLC-ICPMS. Journal of Environmental Monitoring, 10, 136–140.CrossRefGoogle Scholar
  70. Tessier, A., & Campbell, P. G. C. (1987). Partitioning of trace metals in sediments: Relationships with bioavailability. In R. L. Thomas, R. Evans, A. L. Hamilton, M. Munawar, T. B. Reynoldson, & M. H. Sadar (Eds.), Ecological effects of in situ sediment contaminants. Developments in hydrobiology (Vol. 39). Dordrecht: Springer.Google Scholar
  71. Tombacz, E. (2004). The role of reactive surface sites and complexation by humic acids in the interaction of clay minerals and iron oxide particles. Organic Geochemistry, 35, 257.CrossRefGoogle Scholar
  72. Turner, A. (1996). Trace-metal partitioning in estuaries: Importance of salinity and particle concentration. Marine Chemistry, 54, 27–39.CrossRefGoogle Scholar
  73. Turner, A. (2010). Marine pollution from antifouling paint particles. Marine Pollution Bulletin, 60, 159–171.CrossRefGoogle Scholar
  74. Turner, A., Millward, G. E., Schuchardt, B., Schirmer, M., & Prange, A. (1992). Trace metal distribution coefficients in the Weser estuary (Germany). Continental Shelf Research, 12, 1277–1292.CrossRefGoogle Scholar
  75. Ubrihien, R., Taylor, A. M., & Maher, W. A. (2016). Bioaccumulation, oxidative stress and cellular damage in the intertidal gastropod Bembicium namum exposed to a metal contamination gradient. Marine & Freshwater Research, 67, 1–9.CrossRefGoogle Scholar
  76. Underwood, A. C., & Chapman, M. G. (1995). Coastal marine ecology of temperate, Australia (pp. 1–341). Kensington: UNSW Press.Google Scholar
  77. Vogel, C., Kruger, O., Herzel, H., & Adam, C. (2016). Chemical state of mercury and selenium in sewage sludge ash-based P fertilizers. Journal of Hazardous Materials, 313, 179–184.CrossRefGoogle Scholar
  78. Voulvoulis, N., Scrimshaw, N. D., & Lester, J. N. (2002). Comparative environmental assessment of biocides used in antifouling paints. Chemosphere, 47, 789–795.CrossRefGoogle Scholar
  79. Walsh, K., Dunstan, R. H., Murdoch, R. N., Conroy, B. A., Roberts, T. K., & Lake, P. (1994). Bioaccumulation of pollutants and changes in population parameters in the gastropod mollusk Austrocochlea constricta. Archives of Environmental Contamination and Toxicology, 26, 367–373.CrossRefGoogle Scholar
  80. Wang, W., & Fisher, N. S. (1999). Delineating metal accumulation pathways for marine invertebrates. The Science of the Total Environment, 237(238), 459–472.CrossRefGoogle Scholar
  81. Wang, X., Wang, J., & Zhang, J. (2012). Comparisons of three methods for organic and inorganic carbon in calcareous soils of Northwestern China. PLoS ONE, 7, e44334.CrossRefGoogle Scholar
  82. Waring, J., Maher, W. A., & Krikowa, F. (2006). Trace metal bioaccumulation in eight common Australian polychaeta. Journal of Environmental Monitoring, 8, 1149–1157.CrossRefGoogle Scholar
  83. Warnken, J., Dunn, R. J. K., & Teasdale, P. R. (2004). Investigation of recreational boats as a source of copper at anchorage sites using time-integrated diffusive gradients in thin film and sediment measurements. Marine Pollution Bulletin, 49, 833–843.CrossRefGoogle Scholar
  84. Wood, M. A. (1983). Available copper ligands and the apparent bioavailability of copper to natural phytoplankton assemblages. Science of the Total Environment, 28, 51–64.CrossRefGoogle Scholar
  85. Zhuang, J., & Yu, G.-R. (2002). Effects of surface coatings on electrochemical properties and contaminant sorption of clay minerals. Chemosphere, 49, 619–628.CrossRefGoogle Scholar
  86. Zwolsman, J. J. G., Eck, B. T. M., & Van der Weijden, C. H. (1997). Geochemistry of dissolved metals in the Scheldt estuary, southwest Netherlands: Impact of seasonal variability. Geochimica et Cosmochimica Acta, 61, 1635–1652.CrossRefGoogle Scholar

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© Springer Nature B.V. 2018

Authors and Affiliations

  • I. R. McVay
    • 1
  • W. A. Maher
    • 1
  • F. Krikowa
    • 1
  • R. Ubrhien
    • 1
  1. 1.Ecochemistry Laboratory, Institute for Applied EcologyUniversity of CanberraBruceAustralia

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