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

Eccles, Kristin M.; Pauli, Bruce D.; Chan, Hing Man

doi:10.1002/etc.4577

Cited by 15 publications

(14 citation statements)

References 53 publications

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“…This paper also presents the application of a novel method for assessing the spatial patterns of multidimensional ecotoxicology data and builds on our previous work using the MEM method to assess spatial patterns of complex metal exposure in adult wood frogs in northern Alberta [ 27 ]. The results of this analysis identify key hotspots of complex metal and PTE exposure in different species and life stages in the OSR.…”

Section: Discussionmentioning

confidence: 99%

“…Further, to integrate the datasets collected from different species and life stages, we range-normalized (scaled) by species-life stage subgroups to convert all measurements to a common scale (0–1) within each subgroup. Essentially this ranks the exposure within each subgroup [ 27 , 32 ]. This is necessary to control for the differences in bioaccumulation and biomagnification rate of metals and PTEs between species and life stages and allows for contaminant concentrations to be compared and integrated [ 27 , 33 ].…”

Section: Methodsmentioning

confidence: 99%

“…Essentially this ranks the exposure within each subgroup [ 27 , 32 ]. This is necessary to control for the differences in bioaccumulation and biomagnification rate of metals and PTEs between species and life stages and allows for contaminant concentrations to be compared and integrated [ 27 , 33 ]. A workflow of the data preparation and analysis is shown in Fig 2 .…”

Section: Methodsmentioning

confidence: 99%

“…Further, chemicals are measured in different matrices (e.g., feather, muscle, liver). The species, life stage, and matrix differences in chemical concentrations can make it challenging to make direct comparisons between measured biomarkers and can hinder data integration [27]. Additionally, contaminant variables are often highly correlated, which can be problematic for some statistical methods such as regression [28].…”

Section: Introductionmentioning

confidence: 99%

“…Geographic information systems (GIS) are useful platforms to integrate data using a normalization method and assess spatial patterns of exposures to complex mixtures using a spatial principal component analysis (sPCA) [27]. The objective of this study is to demonstrate the use of a geospatial framework and spatial analytical methods to address the challenges associated with integrating and analyzing large wildlife datasets in ecotoxicology.…”

Section: Introductionmentioning

confidence: 99%

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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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Section: Discussionmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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

2020

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A synthetic review of terrestrial biological research from the Alberta oil sands region: 10 years of published literature

Roberts

Bayne

Beausoleil

et al. 2021

Integr Envir Assess & Manag

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In the past decade, a large volume of peer‐reviewed papers has examined the potential impacts of oil and gas resource extraction in the Canadian oil sands (OS). A large proportion focuses on terrestrial biology: wildlife, birds, and vegetation. We provide a qualitative synthesis of the condition of the environment in the oil sands region (OSR) from 2009 to 2020 to identify gaps and progress cumulative effects assessments. Our objectives were to (1) qualitatively synthesize and critically review knowledge from the OSR; (2) identify consistent trends and generalizable conclusions; and (3) pinpoint gaps in need of greater monitoring or research effort. We visualize knowledge and terrestrial monitoring foci by allocating papers to a conceptual model for the OS. Despite a recent increase in publications, focus has remained concentrated on a few key stressors, especially landscape disturbance, and a few taxa of interest. Stressor and response monitoring is well represented, but direct monitoring of pathways (linkages between stressors and responses) is limited. Important knowledge gaps include understanding effects at multiple spatial scales, mammal health effects monitoring, focused monitoring of local resources important to Indigenous communities, and geospatial coverage and availability, including higher attribute resolution in human footprint, comprehensive land cover mapping, and up‐to‐date LiDAR coverage. Causal attribution based on spatial proximity to operations or spatial orientation of monitoring in the region is common but may be limited in the strength of inference that it provides. Integr Environ Assess Manag 2022;18:388–406. © 2021 The Authors. Integrated Environmental Assessment and Management published by Wiley Periodicals LLC on behalf of Society of Environmental Toxicology & Chemistry (SETAC).

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In Silico Methods for Environmental Risk Assessment: Principles, Tiered Approaches, Applications, and Future Perspectives

Astuto

Nicola

Tarazona

et al. 2022

Methods in Molecular Biology

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

Cited by 15 publications

References 53 publications

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

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

A synthetic review of terrestrial biological research from the Alberta oil sands region: 10 years of published literature

In Silico Methods for Environmental Risk Assessment: Principles, Tiered Approaches, Applications, and Future Perspectives

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