Spatial trends in a biomagnifying contaminant: Application of amino acid compound–specific stable nitrogen isotope analysis to the interpretation of bird mercury levels

Dolgova, Svetlana; Popp, Brian N.; Courtoreille, Kevin; Espie, Richard H. M.; Maclean, Bruce; McMaster, Mark E.; Straka, Jason R.; Tetreault, Gerald R.; Wilkie, Steve; Hebert, Craig E.

doi:10.1002/etc.4113

Cited by 34 publications

(30 citation statements)

References 63 publications

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“…In the PAD, as elsewhere, colonial waterbirds are hightropic-level species and therefore can accumulate high levels of biomagnifying contaminants such as Hg (Dolgova et al 2018b). Colonial waterbird eggs from gull and tern colonies in downstream receiving environments of the LAR were therefore used to assess spatial and temporal trends in Hg, arsenic (As), and PACs in eggs (Campbell et al 2013;Hebert, Nordstrom, and Shutt 2010;Hebert et al 2011).…”

Section: Colonial Waterbirdsmentioning

confidence: 99%

“…Colonial waterbird eggs from gull and tern colonies in downstream receiving environments of the LAR were therefore used to assess spatial and temporal trends in Hg, arsenic (As), and PACs in eggs (Campbell et al 2013;Hebert, Nordstrom, and Shutt 2010;Hebert et al 2011). A key methodological development enabled this assessment, namely, the ability to standardize concentrations across space and species through the use of compoundspecific amino acid stable isotope analyses (Dolgova et al 2018a(Dolgova et al , 2018b. This approach can account for different embryonic developmental stages across different colonial waterbird species at different trophic positions.…”

Section: Colonial Waterbirdsmentioning

confidence: 99%

“…Letters above means indicate statistical differences (means with the same letter are not different). Phe = phenylalanine (Dolgova et al 2018b).…”

Section: Colonial Waterbirdsmentioning

confidence: 99%

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Advances in science and applications of air pollution monitoring: A case study on oil sands monitoring targeting ecosystem protection

Brook

Cober

Freemark

et al. 2019

Journal of the Air & Waste Management Association

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The potential environmental impact of air pollutants emitted from the oil sands industry in Alberta, Canada, has received considerable attention. The mining and processing of bitumen to produce synthetic crude oil, and the waste products associated with this activity, lead to significant emissions of gaseous and particle air pollutants. Deposition of pollutants occurs locally (i.e., near the sources) and also potentially at distances downwind, depending upon each pollutant's chemical and physical properties and meteorological conditions. The Joint Oil Sands Monitoring Program (JOSM) was initiated in 2012 by the Government of Canada and the Province of Alberta to enhance or improve monitoring of pollutants and their potential impacts. In support of JOSM, Environment and Climate Change Canada (ECCC) undertook a significant research effort via three components: the Air, Water, and Wildlife components, which were implemented to better estimate baseline conditions related to levels of pollutants in the air and water, amounts of deposition, and exposures experienced by the biota. The criteria air contaminants (e.g., nitrogen oxides [NO x ], sulfur dioxide [SO 2 ], volatile organic compounds [VOCs], particulate matter with an aerodynamic diameter <2.5 μm [PM 2.5 ]) and their secondary atmospheric products were of interest, as well as toxic compounds, particularly polycyclic aromatic compounds (PACs), trace metals, and mercury (Hg). This critical review discusses the challenges of assessing ecosystem impacts and summarizes the major results of these efforts through approximately 2018. Focus is on the emissions to the air and the findings from the Air Component of the ECCC research and linkages to observations of contaminant levels in the surface waters in the region, in aquatic species, as well as in terrestrial and avian species. The existing evidence of impact on these species is briefly discussed, as is the potential for some of them to serve as sentinel species for the ongoing monitoring needed to better understand potential effects, their potential causes, and to detect future changes. Quantification of the atmospheric emissions of multiple pollutants needs to be improved, as does an understanding of the processes influencing fugitive emissions and local and regional deposition patterns. The influence of multiple stressors on biota exposure and response, from natural bitumen and forest fires to climate change, complicates the current ability to attribute effects to air emissions from the industry. However, there is growing evidence of the impact of current levels of PACs on some species, pointing to the need to improve the ability to predict PAC exposures and the key emission source involved. Although this critical review attempts to integrate some of the findings across the components, in terms of ECCC activities, increased coordination or integration of air, water, and wildlife research would enhance deeper scientific understanding. Improved understanding is needed in order to guide the development of longterm mon...

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Section: Colonial Waterbirdsmentioning

confidence: 99%

Section: Colonial Waterbirdsmentioning

confidence: 99%

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Advances in science and applications of air pollution monitoring: A case study on oil sands monitoring targeting ecosystem protection

Brook

Cober

Freemark

et al. 2019

Journal of the Air & Waste Management Association

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“…Annual sampling campaigns in the wildlife contaminants and toxicology monitoring program in JOSM measured a selected suite of chemical contaminants in wood frogs (Lithobates sylvaticus); fur-bearing mammals including river otter (Lontra canadensis), mink (Neovision vision), fisher (Martes pennant), and marten (Martes Americana); birds including the eggs of Caspian Terns (Hydroprogne caspia) and California Gulls (Larus californicus), and tree swallow (Tachycineta bicolor) nestlings; and a variety of aboveground and belowground plant matter. In the wildlife contaminants monitoring program, exposure to contaminants was measured in collected tissues, including liver, feathers, and eggs [8][9][10][11][12][13]. Programs under JOSM also monitored abiotic matrices, including air, water, and aerial deposition of contaminants, including in snow.…”

Section: Introductionmentioning

confidence: 99%

Geospatial analysis of the patterns of chemical exposures among biota in the Canadian Oil Sands Region

2020

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Understanding the patterns of chemical exposure among biota across a landscape is challenging due to the spatial heterogeneity and complexity of the sources, pathways, and fate of the different chemicals. While spatially-driven relationships between contaminant sources and biota body burdens of a single chemical are commonly modelled, there has been little effort on modelling chemical mixtures across multiple wildlife species in the Canadian Oil Sands region. In this study, we used spatial principal components analysis (sPCA) to assess spatial patterns of the body burdens of 22 metals and Potentially Toxic Elements (PTEs) in 492 individual wildlife, including fur-bearing mammals, colonial waterbirds, and amphibians collected from the Canadian Oil Sands region in Canada. Spatial analysis and mapping both indicate that some of the complex exposures in the studied biota are distributed randomly across a landscape, which suggests background or non-point source exposures. In contrast, the pattern of exposure for seven metals and PTEs, including mercury, vanadium, lead, rubidium, lithium, strontium, and barium, exhibited a clustered pattern to the east of the open-pit mining area and in regions downstream of oil sands development which indicates point-source input. This analysis demonstrated useful methods for integrating monitoring datasets and identifying sources and potential drivers of exposure to chemical mixtures in biota across a landscape. These results can be used to support an adaptive monitoring program by identifying regions needing additional monitoring, health impact assessments, and possible intervention strategies.

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“…We also provide a proof-of-concept example for demonstration purposes of how to assess the spatial co-occurrence between exposures and responses. (Hebert et al 2013;Dolgova et al 2018), plants (Boutin and Carpenter 2017), and terrestrial and semiaquatic mammals (Thomas et al 2017). Biological samples from the monitoring activity were geolocated, and tissues (and some abiotic samples) were analyzed for a variety of contaminants, including metals and PACs, and in some species, health indicators were measured, including thyroid hormones (triiodothyronine and thyroxine) and cortisol (Government of Canada 2017).…”

Section: Introductionmentioning

confidence: 99%

The Use of Geographic Information Systems for Spatial Ecological Risk Assessments: An Example from the Athabasca Oil Sands Area in Canada

Eccles

Pauli

Chan

2019

Enviro Toxic and Chemistry

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There is an acknowledged need in ecotoxicology for methods that integrate spatial analyses in risk assessment. This has resulted in the emergence of landscape ecotoxicology, a subdiscipline of ecotoxicology. However, landscape ecotoxicology has yet to become common practice in risk assessment due to the underdevelopment of techniques and a lack of standardized methods. In the present study, we demonstrate how geographic information systems (GISs) can serve as a standardized platform to integrate data, assess spatial patterns of ecotoxicological data for multiple species, and assess relationships between chemical mixture exposures and effects on biota for landscape ecotoxicological risks assessment. We use data collected under the Joint Oil Sands Monitoring Program in the Athabasca Oil Sands Region in Alberta, Canada. This dataset is composed of concentrations of contaminants including metals and polycyclic aromatic compounds, and health endpoints measured in 1100 biological samples, including tree swallows, amphibians, gull and tern eggs, plants, and mammals. We present 3 examples using a GIS as a platform and geospatial analysis to: 1) integrate data and assess spatial patterns of contaminant exposure in the region, 2) assess spatial patterns of exposures to complex mixtures, and 3) examine patterns of exposures and responses across the landscape. We summarize the methods used in the present study into a workflow for ease of use. The GIS methods allow researchers to identify hot spots of contamination, use georeferenced monitoring data to derive quantitative exposure‐response relationships, and assess complex exposures with more realism. Environ Toxicol Chem 2019;38:2797–2810. © 2019 SETAC

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Spatial trends in a biomagnifying contaminant: Application of amino acid compound–specific stable nitrogen isotope analysis to the interpretation of bird mercury levels

Cited by 34 publications

References 63 publications

Advances in science and applications of air pollution monitoring: A case study on oil sands monitoring targeting ecosystem protection

Advances in science and applications of air pollution monitoring: A case study on oil sands monitoring targeting ecosystem protection

Geospatial analysis of the patterns of chemical exposures among biota in the Canadian Oil Sands Region

The Use of Geographic Information Systems for Spatial Ecological Risk Assessments: An Example from the Athabasca Oil Sands Area in Canada

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