Your search keyword '"Mckindsey, C.W."' showing total 2 results

1. Trace Metal Residues in Marine Mussels: A Global Survey

Author

Natural Sciences and Engineering Research Council of Canada, Ministry of Business, Innovation, and Employment (New Zealand), University of Cape Town, Universidad Autónoma de Baja California, CSIC - Instituto Español de Oceanografía (IEO), Ministerio de Agricultura, Alimentación y Medio Ambiente (España), Ministerio de Economía y Competitividad (España), Cledon, M., Tremblay, L.A., Griffiths, C., Fadhlaoui, M., Champeau, O., Albentosa, Marina, Besada, Victoria, Fernández, V.H, McKindsey, C.W., Bendell, L.I., Zhang, B., Garcia-Esquivel, Z., Curiel, S., Brar, S.K., Kumar, P., Laroche, O., Couturee, P., Natural Sciences and Engineering Research Council of Canada, Ministry of Business, Innovation, and Employment (New Zealand), University of Cape Town, Universidad Autónoma de Baja California, CSIC - Instituto Español de Oceanografía (IEO), Ministerio de Agricultura, Alimentación y Medio Ambiente (España), Ministerio de Economía y Competitividad (España), Cledon, M., Tremblay, L.A., Griffiths, C., Fadhlaoui, M., Champeau, O., Albentosa, Marina, Besada, Victoria, Fernández, V.H, McKindsey, C.W., Bendell, L.I., Zhang, B., Garcia-Esquivel, Z., Curiel, S., Brar, S.K., Kumar, P., Laroche, O., and Couturee, P.

Abstract

Pressures from anthropogenic activities are causing degradation of estuarine and coastal ecosystems around the world. Trace metals are key pollutants that are released and can partition in a range of environmental compartments, to be ultimately accumulated in exposed biota. The level of pressure varies with locations and the range and intensity of anthropogenic activities. The present study measured residues of trace metals in Mytilus mussel species collected from a range of locations around the world in areas experiencing a gradient of anthropogenic pressures that we classified as low, moderate, or high impact. The data showed no grouping/impact level when sampling sites in all countries were incorporated in the analysis, but there was significant clustering/impact level for most countries. Overall, high-impact areas were characterized by elevated concentrations of zinc, lead, nickel, and arsenic, whereas copper and silver were detected at higher concentrations in medium-impact areas. Finally, whereas most metals were found at lower concentrations in areas classified as low impact, cadmium was typically elevated in these areas. The present study provides a unique snapshot of worldwide levels of coastal metal contamination through the use of Mytilus species, a well-established marine biomonitoring tool

Published

2021

2. An integrated ecosystem approach for assessing the potential role of cultivated bivalve shells as part of the carbon trading system

Author

Filgueira, Ramón, Byron, C.J., Comeau, L.A., Costa-Pierce, B., Cranford, Peter J., Ferreira, J.G., Grant, J., Guyondet, T., Jansen, H.M., Landry, T., McKindsey, C.W., Petersen, Jens Kjerulf, Reid, G.K., Robinson, S.M.C., Small, A., Sonier, R., Strand, Ø., Strohmeier, T., Filgueira, Ramón, Byron, C.J., Comeau, L.A., Costa-Pierce, B., Cranford, Peter J., Ferreira, J.G., Grant, J., Guyondet, T., Jansen, H.M., Landry, T., McKindsey, C.W., Petersen, Jens Kjerulf, Reid, G.K., Robinson, S.M.C., Small, A., Sonier, R., Strand, Ø., and Strohmeier, T.

Abstract

The role of bivalve mariculture in the CO2 cycle has been commonly evaluated as the balance between respiration, shell calcium carbonate sequestration and CO2 release during biogenic calcification. However, this approach neglects the ecosystem implications of cultivating bivalves at high densities, e.g. the impact on phytoplankton dynamics and benthic-pelagic coupling, which can significantly contribute to the CO2 cycle. Therefore, an ecosystem approach that accounts for the trophic interactions of bivalve aquaculture, including dissolved and particulate organic and inorganic carbon cycling, is needed to provide a rigorous assessment of the role of bivalve mariculture in the CO2 cycle. On the other hand, the discussion about the inclusion of shells of cultured bivalves into the carbon trading system should be framed in the context of ecosystem goods and services. Humans culture bivalves with the aim of producing food, not sequestering CO2 in their shells, therefore the main ecosystem good provided by bivalve aquaculture is meat production, and shells should be considered as by-products of this human activity. This reasoning is key to split the CO2 released due to respiration between meat and shell when constructing a specific CO2 budget for shells for evaluating the potential of including bivalve shells, and not the whole organism, in the carbon trading system. Concluding, an integrated ecosystem approach as well as an understanding of the ecosystems goods and services of bivalve aquaculture are two essential requisites for providing a reliable assessment of the role of bivalve shells in the CO2 cycle

Published

2015