Ecologically-Driven Exposure Pathways Science Team
The Team Determines Factors That Influence Fish and Wildlife Exposure
to toxicants such as mercury in the environment
Scientists Can Sample Tissues and Blood in Small Birds Without Harm
to understand factors such as maternal transfer of contaminants to offspring
The Team Studies Factors that Influence Exposure Risk in Mammals
such as foraging and fasting behavior in elephant seals
Factors that Influence Pathogen Transmission are Identified
Advanced Techniques are used to Understand Contaminant Sources
The Ecologically-Driven Exposure Pathways Integrated Science Team identifies how ecological pathways and physiological processes within a single organism can alter exposure and toxicity of contaminants and pathogens and seek to understand outcomes at different scales from individuals to populations and ecosystems.
Contaminant and pathogen exposure alone does not necessarily result in adverse health outcomes in fish, wildlife, or humans. There are numerous pathways and processes that can alter the toxicity of naturally occurring and human-made contaminants in the environment.
The team uses their broad scientific expertise in hydrology, geochemistry, biology, and ecotoxicology to understand the complexities associated with the movement of toxicants and pathogens through the environment and within individual organisms. That information is used to determine how, where, and when exposure occurs and if exposure results in health risks to wildlife and humans.
Current Science Questions and Activities
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What are the various ecological factors, such as habitats and foraging strategies, that influence the pathways of contaminant exposure, health risks to fish and wildlife?
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What are the pathways of antimicrobial resistance in the environment?
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What are the major intrinsic and extrinsic drivers of mercury exposure and risk to humans, fish, and wildlife at a global scale?
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What are the internal physiological determinants such as metababolism, transfer of mercury to offspring, changes in body mass, and molting that influence exposure and health risks in fish and wildlife?
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How do the internal factors differ among species and life stages?
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What are the Influences of landscape alterations, perturbations, and restoration on pathways and movement of contaminants through ecosystems and bioaccumulation into the food web of aquatic biota?
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Do multiple types and chemical mixtures have additive, synergistic, or antagonistic effects that influence the health of fish and wildlife?
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What are the internal and external drivers and regulators of human exposure to mercury?
- What is the risk of pathogen exposure and transmission among wildlife, livestock, and humans?
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What are the key environmental factors that control the viability of avian influenza virus shed by wild birds and what are the key environmental pathways of exposure and transmission of the virus?
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What is the role of soil, water, and vegetation in disease transmission such as Chronic Wasting Disease?
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How do invasive species influence the timing of contaminant uptake and bioaccumulation in fish and wildlife?
USGS science related to this science team’s activities.
The following are the data releases from this science team’s research activities.
Elk GPS collar data from National Elk Refuge (2006-2015)
2003 Blood Corticosterone Common Loons: Data
Below are publications associated with this science team.
Isotope fractionation from In Vivo methylmercury detoxification in waterbirds
Surface-air mercury fluxes and a watershed mass balance in forested and harvested catchments
Temporal influences on selenium partitioning, trophic transfer, and exposure in a major U.S. river
Long-term trends in regional wet mercury deposition and lacustrine mercury concentrations in four lakes in Voyageurs National Park
Why Lyme disease is common in the northern US, but rare in the south: The roles of host choice, host-seeking behavior, and tick density
Linking field and laboratory studies: Reproductive effects of perfluorinated substances on avian populations
Age‐ and sex‐related dietary specialization facilitate seasonal resource partitioning in a migratory shorebird
Variation in metal concentrations across a large contamination gradient is reflected in stream but not linked riparian food webs
Evidence for continental-scale dispersal of antimicrobial resistant bacteria by landfill-foraging gulls
From forests to fish: Mercury in mountain lake food webs influenced by factors at multiple scales
Mercury exposure in mammalian mesopredators inhabiting a brackish marsh
The influence of legacy contamination on the transport and bioaccumulation of mercury within the Mobile River Basin
The Ecologically-Driven Exposure Pathways Integrated Science Team identifies how ecological pathways and physiological processes within a single organism can alter exposure and toxicity of contaminants and pathogens and seek to understand outcomes at different scales from individuals to populations and ecosystems.
Contaminant and pathogen exposure alone does not necessarily result in adverse health outcomes in fish, wildlife, or humans. There are numerous pathways and processes that can alter the toxicity of naturally occurring and human-made contaminants in the environment.
The team uses their broad scientific expertise in hydrology, geochemistry, biology, and ecotoxicology to understand the complexities associated with the movement of toxicants and pathogens through the environment and within individual organisms. That information is used to determine how, where, and when exposure occurs and if exposure results in health risks to wildlife and humans.
Current Science Questions and Activities
-
What are the various ecological factors, such as habitats and foraging strategies, that influence the pathways of contaminant exposure, health risks to fish and wildlife?
-
What are the pathways of antimicrobial resistance in the environment?
-
What are the major intrinsic and extrinsic drivers of mercury exposure and risk to humans, fish, and wildlife at a global scale?
-
What are the internal physiological determinants such as metababolism, transfer of mercury to offspring, changes in body mass, and molting that influence exposure and health risks in fish and wildlife?
-
How do the internal factors differ among species and life stages?
-
What are the Influences of landscape alterations, perturbations, and restoration on pathways and movement of contaminants through ecosystems and bioaccumulation into the food web of aquatic biota?
-
Do multiple types and chemical mixtures have additive, synergistic, or antagonistic effects that influence the health of fish and wildlife?
-
What are the internal and external drivers and regulators of human exposure to mercury?
- What is the risk of pathogen exposure and transmission among wildlife, livestock, and humans?
-
What are the key environmental factors that control the viability of avian influenza virus shed by wild birds and what are the key environmental pathways of exposure and transmission of the virus?
-
What is the role of soil, water, and vegetation in disease transmission such as Chronic Wasting Disease?
-
How do invasive species influence the timing of contaminant uptake and bioaccumulation in fish and wildlife?
USGS science related to this science team’s activities.
The following are the data releases from this science team’s research activities.
Elk GPS collar data from National Elk Refuge (2006-2015)
2003 Blood Corticosterone Common Loons: Data
Below are publications associated with this science team.