Your search keyword '"David R. Edmunds"' showing total 29 results

1. Estimating traffic volume and road age in Wyoming to inform resource management planning: An application with wildlife-vehicle collisions

Author

Richard D. Inman, Benjamin S. Robb, Michael S. O’Donnell, David R. Edmunds, Matthew J. Holloran, and Cameron L. Aldridge

Subjects

Energy development, Graph theory, Machine learning, Road age, Traffic volume, Wyoming, Ecology, QH540-549.5

Abstract

Road networks and their associated vehicular traffic disturb many terrestrial systems, but inventories of roads used to assess these effects often focus on the ‘where’ (e.g., local road type and density) and neglect the ‘when’ (e.g., temporal disturbance) or ‘how much’ (e.g., traffic volume disturbance). We developed annual estimates of the ‘when’ (road age) and ‘how much’ (vehicular traffic volume) across 148,172 km of highways, arterials, collectors, local, and gravel/graded roads within the state of Wyoming for the years 1986 to 2020 to provide a comprehensive dataset for future ecological investigations. We leveraged a suite of ancillary data on surface disturbances (e.g., oil & gas drilling operations, wind turbines, and open pit mines) with known establishment dates and combined them using graph theory and centrality metrics to estimate the age of each road. We then predicted traffic volume obtained from the Wyoming Department of Transportation for each year across Wyoming using a machine learning method, XGBoost, and a separate set of spatial covariates hypothesized to explain traffic patterns across large regions. We found that 132,476 km of these roads likely existed before 1986, but that 16,693 km (10.7 %) of roads have been built since 1986. Overall, our estimates of road age were 89 % accurate when assessed on a subset of 1,330 roads with high-resolution aerial imagery. Mean absolute error for predicting traffic volume ranged from 35.2 to 77.9 annual average daily traffic (aadt) for trucks and 269.2 to 516.7 aadt for all-vehicles across the 35 years. We found that mean traffic volume across the state increased by 23 % for both truck-only traffic and all vehicular traffic from 1986 to 2020. However, changes in traffic volume have varied substantially across the state (e.g., 100 % increases in volume in some areas, while other areas experienced declines of up to 1,786 %). We also illustrate a novel application of these data by predicting rates of reported wildlife-vehicle collisions (WVCs) along a subset of roads. We found evidence of a non-linear relationship that supported a threshold hypothesis for WVCs, wherein increases in traffic volume equate to increases in WVCs up to a threshold, above which increases in traffic volume result in declines in WVCs. The data provided here will enable better-informed studies of road ecology to address how roads may affect wildlife populations and key ecosystems across Wyoming.

Published

2024

2. PopEquus: A predictive modeling tool to support management decisions for free‐roaming horse populations

Author

Brian Folt, Kathryn A. Schoenecker, L. Stefan Ekernas, David R. Edmunds, and Mark Hannon

Subjects

decision analysis, Equus caballus, fertility control, population model, trade‐offs, wildlife management, Ecology, QH540-549.5

Abstract

Abstract Feral horse (Equus caballus) population management is a challenging problem around the world because populations often exhibit density‐independent growth, can exert negative ecological effects on ecosystems, and require great cost to be managed. However, strong value‐based connections between people and horses cause contention around management decisions. To help make informed decisions, natural resource managers might benefit from more detailed understanding of how horse management alternatives, including combinations of removals and fertility control methods, could achieve objectives of sustainable, multiple‐use ecosystems while minimizing overall horse handling and fiscal costs. Here, we describe a modeling tool that simulates horse management alternatives and estimates trade‐offs in predicted metrics related to population size, animal handling, and direct costs of management. The model considers six management actions for populations (removals for adoption or long‐term holding; fertility control treatment with three vaccines, intrauterine devices, and mare sterilization), used alone or in combination. We simulated 19 alternative management scenarios at 2‐, 3‐, and 4‐year management return intervals and identified efficiency frontiers among alternatives for trade‐offs between predicted population size and six management metrics. Our analysis identified multiple alternatives that could maintain populations within target population size ranges, but some alternatives (e.g., removal and mare sterilization, removal and GonaCon treatment) performed better at minimizing overall animal handling requirements and management costs. Cost savings increased under alternatives with more effective, longer lasting fertility control techniques over longer management intervals compared with alternatives with less‐effective, shorter lasting fertility control techniques. We built a user‐friendly website application, PopEquus, that decision makers and interested individuals can use to simulate management alternatives and evaluate trade‐offs among management and cost metrics. Our results and website application provide quantitative trade‐off tools for horse population management decisions and can help support value‐based management decisions for wild or feral horse populations and ecosystems at local and regional scales around the world.

Published

2023

3. A targeted annual warning system developed for the conservation of a sagebrush indicator species

Author

Brian G. Prochazka, Peter S. Coates, Michael S. O'Donnell, David R. Edmunds, Adrian P. Monroe, Mark A. Ricca, Gregory T. Wann, Steve E. Hanser, Lief A. Wiechman, Kevin E. Doherty, Michael P. Chenaille, and Cameron L. Aldridge

Subjects

Adaptive management, Sagebrush, Sage-grouse, Targeted monitoring, Triggers, Warning system, Ecology, QH540-549.5

Abstract

A fundamental goal of population ecologists is to identify drivers responsible for temporal variation in abundance. Understanding whether variation is associated with environmental stochasticity or anthropogenic disturbances, which are more amenable to management action, is crucial yet difficult to achieve. Here, we present a hierarchical monitoring framework that models rates of change in abundance from spatially structured populations and identifies when local declines fall out of synchrony with trends at larger spatial scales. Importantly, the framework provides signals that alert managers to the categorical significance of observed declines while avoiding signals where declines result from drivers operating at larger spatial scales (e.g., periodic reductions in primary productivity owing to drought). We demonstrate utility through application to a rapidly declining sagebrush (Artemisia spp.) indicator species (greater sage-grouse; Centrocercus urophasianus) using 30 years (1990–2019) of count data collected from greater than 4,400 leks (habitual breeding sites) distributed across the western United States. Results revealed population declines, immediately preceding triggers (2–4-year period), ranging between 58 and 68%. Conversely, population trends unassociated with triggers showed little-to-no sign of decline. Retrospective application of the monitoring framework indicated an average annual rate of 1.7% of leks or 1.3% of neighborhood clusters (lek aggregations) would have required management intervention to reverse range-wide declines and stabilize the U.S. population as a whole.

Published

2023

4. A regionally varying habitat model to inform management for greater sage-grouse persistence across their range

Author

Gregory T. Wann, Nathan D. Van Schmidt, Jessica E. Shyvers, Bryan C. Tarbox, Megan M. McLachlan, Michael S. O’Donnell, Anthony J. Titolo, Peter S. Coates, David R. Edmunds, Julie A. Heinrichs, Adrian P. Monroe, and Cameron L. Aldridge

Subjects

Collaborative management, Centrocercus urophasianus, Greater sage-grouse, Habitat suitability model, Lek persistence, Mixed effects model, Ecology, QH540-549.5

Abstract

Identifying habitat needs for species with large distributions is challenging because species-habitat associations may vary across scales and regions (spatial nonstationarity). Furthermore, management efforts often cross jurisdictional boundaries, complicating the development of cohesive conservation strategies among management entities. The greater sage-grouse (Centrocercus urophasianus) is a rapidly declining species that spans 11 U.S. states and responds to habitat conditions across a wide range of spatial scales and regions. Allowing for regional variance in species-habitat associations and suitability predictions could systematically identify important habitats at levels relevant to management. We collaboratively developed a model with Bureau of Land Management (BLM) biologists that: (1) evaluated the scale of effect for different environmental covariates; (2) accounted for regional differences in population-level responses; and (3) predicted probabilities of persistence across the U.S. occupied range. We modeled range-wide lek persistence data (6615 communal breeding sites classified as active or inactive) as a function of environmental covariates. Environmental covariates included sagebrush cover, pinyon-juniper cover, topography, precipitation, point and line disturbance densities, and landscape configuration metrics. Our model treated habitat assessment areas – regionally delineated by BLM biologists – as random intercepts and slopes that allowed for geographic variation in species-habitat associations and predicted probabilities of lek persistence. Our final model indicated support for 12 environmental covariates predicting lek persistence at scales extending between 1- to 15-km radii from lek centers, and a covariate measuring distance to the occupied range boundary. Five of these covariates showed significant regionally varying responses: sagebrush clumpiness (a measure of habitat aggregation), pinyon-juniper cover, point disturbance of anthropogenic features such as energy infrastructure and communication towers, elevation, and a topographic index associated with mesic habitats. This spatial nonstationarity indicates unitary range-wide recommendations, or rules-of-thumb with respect to their effects on lek persistence, may be problematic for these environmental conditions. For covariates that did not include random slopes, and which were potentially amenable to management actions, we found that leks were predicted to become extirpated when sagebrush cover fell below 9.6 % (summarized at the 3.2-km radius extent), and the proportion of classified sagebrush habitat fell below 0.7 (1-km). We produced a continuous predictive probability surface of lek persistence which we binned based on model sensitivity thresholds to produce habitat quality categories. The highest quality habitat (capturing 50 % of active leks) covered 25.5 % of the occupied range, while the combined lowest through highest quality habitats (capturing 95 % of active leks) covered 65.0 %. Accommodating regional environmental differences in models that are relevant to habitat management planning will help ensure their applicability to targeted goals. Continuous collaboration between modelers and land managers early in the modeling process increases the likelihood of this outcome.

Published

2023

5. Spatial scale selection for informing species conservation in a changing landscape

Author

Adrian P. Monroe, Julie A. Heinrichs, Ashley L. Whipple, Michael S. O'Donnell, David R. Edmunds, and Cameron L. Aldridge

Subjects

Artemisia spp., Centrocercus urophasianus, density dependence, greater sage‐grouse, population dynamics, sagebrush, Ecology, QH540-549.5

Abstract

Abstract Identifying the relevant spatial scale at which species respond to features in a landscape (scale of effect) is a pressing research need as managers work to reduce biodiversity loss amid a variety of environmental challenges. Until recently, researchers often evaluated a subset of potential scales of effect inferred from previous studies in other locations, often based on different biological responses and environmental variables. These approaches, however, can create uncertainty as to whether relevant spatial scales were identified, and whether the effects of environmental variables at scale were accurately estimated. Identifying scales of effect is particularly relevant for the greater sage‐grouse (Centrocercus urophasianus), a sagebrush‐obligate species of conservation concern requiring large areas of intact sagebrush cover (Artemisia spp.) for habitat. We demonstrate the application of a scale selection approach that jointly estimates the scale of effect and the effect of sagebrush cover on trends in population size using counts from 584 sage‐grouse leks in southwestern Wyoming (2003–2019) and annual estimates of sagebrush cover from a remote sensing product. From this approach, we estimated a positive effect of mean sagebrush cover with a 95% probability that the scale of effect occurred within 5.02 km of leks. In an average year, we found that lower levels of sagebrush cover within these estimated scales could support increasing trends in sage‐grouse population size when populations were small, but higher levels of sagebrush cover were needed to sustain growing populations when populations were larger. With standardized monitoring and annual estimates of vegetation from remote sensing, this scale selection approach can be applied to identify relevant scales for other populations, species, and biological responses such as demography and movement.

Published

2022

6. Designing multi‐scale hierarchical monitoring frameworks for wildlife to support management: a sage‐grouse case study

Author

Michael S. O'Donnell, David R. Edmunds, Cameron L. Aldridge, Julie A. Heinrichs, Peter S. Coates, Brian G. Prochazka, and Steve E. Hanser

Subjects

adaptive management, Centrocercus urophasianus, graph theory, greater sage‐grouse, habitat connectivity, hierarchically nested clusters, Ecology, QH540-549.5

Abstract

Abstract Population monitoring is integral to the conservation and management of wildlife; yet, analyses of population demographic data rarely consider processes occurring across spatial scales, potentially limiting the effectiveness of adaptive management. Therefore, we developed a method to identify hierarchical levels of organization (i.e., populations) to define multiple spatial scales, specifically intended to help guide appropriate conservation and management actions. This approach can support mobile species with high site fidelity where surveys occur on birthing/breeding grounds or migratory stopovers. Our approach used a graph‐based clustering algorithm (Spatial K'luster Analysis by Tree Edge Removal) that explicitly included habitat selection information at multiple scales and further refined with constraint‐based rules. We applied these concepts to greater sage‐grouse leks (breeding grounds), a species of conservation concern, in two different ecological contexts (Nevada and Wyoming, USA). The constraint‐based rules accounted for inter‐lek movement distances based on literature and field studies in Nevada from 2012 to 2016, included methods to support a spatially balanced monitoring design, and identified barriers to movements among leks based on resistance surfaces. We evaluated the performance of our hierarchical clusters in Nevada using independent data from radio‐marked sage‐grouse, and we found the finest‐scaled cluster level captured ~90% of sage‐grouse movements and mid‐level scales captured ~97–99% of movements. We expected comparable performance for Wyoming, where we lacked radio‐marked sage‐grouse for an evaluation, because genetic studies estimate similar dispersal distances to our ~15 km inter‐lek movement distance in Nevada. For sage‐grouse and other mobile species with high site fidelity, our approach to defining these frameworks could prove valuable for conservation and management applications, such as improving estimation of scale‐dependent population trends and guiding the prescription of management actions at spatial scales that align with identified threats. Specific to sage‐grouse, our analysis sets the stage for designing a monitoring framework that relies on comparison of short‐ and long‐term population trends across our defined spatial scales and identifies and disentangles factors driving local (e.g., habitat quality) and regional (e.g., climate) population changes, thereby supporting scale‐dependent management and research needs for adaptive management practices.

Published

2019

7. Using neutral landscape models to evaluate the umbrella species concept in an ecotone

Author

Courtney J. Duchardt, Adrian P. Monroe, David R. Edmunds, Matthew J. Holloran, Alison G. Holloran, and Cameron L. Aldridge

Subjects

Ecology, Geography, Planning and Development, Nature and Landscape Conservation

Published

2023

8. Defining fine‐scaled population structure among continuously distributed populations

Author

Michael S. O'Donnell, David R. Edmunds, Cameron L. Aldridge, Julie A. Heinrichs, Adrian P. Monroe, Peter S. Coates, Brian G. Prochazka, Steve E. Hanser, and Lief A. Wiechman

Subjects

Ecological Modeling, Ecology, Evolution, Behavior and Systematics

Published

2022

9. Synthesizing and analyzing long-term monitoring data: A greater sage-grouse case study.

Author

Michael S. O'Donnell, David R. Edmunds, Cameron L. Aldridge, Julie A. Heinrichs, Adrian P. Monroe, Peter S. Coates, Brian G. Prochazka, Steve E. Hanser, Lief A. Wiechman, Thomas J. Christiansen, Avery A. Cook, Shawn P. Espinosa, Lee J. Foster, Kathleen A. Griffin, Jesse L. Kolar, Katherine S. Miller, Ann M. Moser, Thomas E. Remington, Travis J. Runia, Leslie A. Schreiber, Michael A. Schroeder, San J. Stiver, Nyssa I. Whitford, and Catherine S. Wightman

Published

2021

10. A genetic warning system for a hierarchically structured wildlife monitoring framework

Author

Shawna J. Zimmerman, Cameron L. Aldridge, Michael S. O'Donnell, David R. Edmunds, Peter S. Coates, Brian G. Prochazka, Jennifer A. Fike, Todd B. Cross, Bradley C. Fedy, and Sara J. Oyler‐McCance

Subjects

Ecology

Abstract

Genetic variation is a well-known indicator of population fitness yet is not typically included in monitoring programs for sensitive species. Additionally, most programs monitor populations at one scale, which can lead to potential mismatches with ecological processes critical to species' conservation. Recently developed methods generating hierarchically nested population units (i.e., clusters of varying scales) for greater sage-grouse (Centrocercus urophasianus) have identified population trend declines across spatiotemporal scales to help managers target areas for conservation. The same clusters used as a proxy for spatial scale can alert managers to local units (i.e., neighborhood-scale) with low genetic diversity, further facilitating identification of management targets. We developed a genetic warning system utilizing previously developed hierarchical population units to identify management-relevant areas with low genetic diversity within the greater sage-grouse range. Within this warning system we characterized conservation concern thresholds based on values of genetic diversity and developed a statistical model for microsatellite data to robustly estimate these values for hierarchically nested populations. We found that 41 of 224 neighborhood-scale clusters had low genetic diversity, 23 of which were coupled with documented local population trend decline. We also found evidence of cross-scale low genetic diversity in the small and isolated Washington population, unlikely to be reversed through typical local management actions alone. The combination of low genetic diversity and a declining population suggests relatively high conservation concern. Our findings could further facilitate conservation action prioritization in combination with population trend assessments and (or) local information, and act as a base-line of genetic diversity for future comparison. Importantly, the approach we used is broadly applicable across taxa. This article is protected by copyright. All rights reserved.

Published

2023

11. Prioritizing landscapes for grassland bird conservation with hierarchical community models

Author

Adrian P. Monroe, Timothy J. Assal, Cameron L. Aldridge, David R. Edmunds, Alison G. Holloran, and Matthew J. Holloran

Subjects

education.field_of_study, geography.geographical_feature_category, Distance sampling, Ecology, Geography, Planning and Development, Population, Wildlife, Vegetation, Grassland, Geography, Habitat, Landscape ecology, Bird conservation, education, Nature and Landscape Conservation

Abstract

Context Given widespread population declines of birds breeding in North American grasslands, management that sustains wildlife while supporting rancher livelihoods is needed. However, management effects vary across landscapes, and identifying areas with the greatest potential bird response to conservation is a pressing research need. Objectives We developed a hierarchical modeling approach to study grassland bird response to habitat factors at multiple scales and levels. We then identified areas to prioritize for implementing a bird-friendly ranching program. Methods Using bird survey data from grassland passerine species and 175 sites (2009–2018) across northeast Wyoming, USA, we fit hierarchical community distance sampling models and evaluated drivers of site-level density and regional-level distribution. We then created spatially-explicit predictions of bird density and distribution for the study area and predicted outcomes from pasture-scale management scenarios. Results Cumulative overlap of species distributions revealed areas with greater potential community response to management. Within each species’ potential regional-level distribution, the grassland bird community generally responded negatively to cropland cover and vegetation productivity at local scales (up to 10 km of survey sites). Multiple species declined with increasing bare ground and litter cover, shrub cover, and grass height measured within sites. Conclusions We demonstrated a novel approach to multi-scale and multi-level prioritization for grassland bird conservation based on hierarchical community models and extensive population monitoring. Pasture-scale management scenarios also suggested the examined community may benefit from less bare ground cover and shorter grass height. Our approach could be extended to other bird guilds in this region and beyond.

Published

2021

12. Quantile regression estimates of animal population trends

Author

Brian S. Cade, David R. Edmunds, and Douglas S. Ouren

Subjects

Ecology, General Earth and Planetary Sciences, Ecology, Evolution, Behavior and Systematics, Nature and Landscape Conservation, General Environmental Science

Published

2022

13. Range-wide greater sage-grouse hierarchical monitoring framework—Implications for defining population boundaries, trend estimation, and a targeted annual warning system

Author

Cameron L. Aldridge, David R. Edmunds, Steve E. Hanser, Lief A. Wiechman, Gregory T. Wann, Peter S. Coates, Mark A. Ricca, Adrian P. Monroe, Michael P. Chenaille, Michael S. O'Donnell, and Brian G. Prochazka

Subjects

education.field_of_study, Warning system, Range (biology), Population, Environmental science, Sage grouse, Physical geography, education, Trend estimation

Published

2021

14. U.S. Geological Survey science for the Wyoming Landscape Conservation Initiative—2018 annual report

Author

Michael S. O'Donnell, David R. Edmunds, Collin G. Homer, Daniel J. Manier, Kirk A. Miller, Matthew J. Kauffman, Aaron N. Johnston, Steven Aulenbach, Tabitha A. Graves, Christopher Huber, Teal B. Wyckoff, Patrick J. Anderson, Anna D. Chalfoun, Julie A. Heinrichs, Annika W. Walters, Jason S. Alexander, Steve Germaine, Zachary H. Bowen, Adrian P. Monroe, Ryan R. McShane, Linda C. Zeigenfuss, Anna C. Ortega, Cameron L. Aldridge, Daniel J. Wieferich, Geneva W. Chong, Timothy J. Assal, Cheryl A. Eddy-Miller, and Holly E. Copeland

Subjects

Geography, Geological survey, Landscape conservation, Annual report, Archaeology

Published

2021

15. Correction to: Prioritizing landscapes for grassland bird conservation with hierarchical community models

Author

Timothy J. Assal, David R. Edmunds, Alison G. Holloran, Cameron L. Aldridge, Adrian P. Monroe, and Matthew J. Holloran

Subjects

Sustainable development, Geography, geography.geographical_feature_category, Ecology, Agroforestry, Nature Conservation, Ecology (disciplines), Geography, Planning and Development, Landscape ecology, Bird conservation, Grassland, Nature and Landscape Conservation

Published

2021

16. Prioritizing restoration areas to conserve multiple sagebrush-associated wildlife species

Author

David R. Edmunds, Adrian P. Monroe, Michael S. O'Donnell, Julie A. Heinrichs, Courtney J. Duchardt, and Cameron L. Aldridge

Subjects

0106 biological sciences, geography, Decision support system, geography.geographical_feature_category, Steppe, Range (biology), business.industry, 010604 marine biology & hydrobiology, Environmental resource management, Wildlife, Biodiversity, 010603 evolutionary biology, 01 natural sciences, Habitat destruction, Habitat, Ecosystem, business, Ecology, Evolution, Behavior and Systematics, Nature and Landscape Conservation

Abstract

Strategic restoration of altered habitat is one method for addressing worldwide biodiversity declines. Within the sagebrush steppe of western North America, habitat degradation has been linked to declines in many species, making restoration a priority for managers; however, limited funding, spatiotemporal variation in restoration success, and the need to manage for diverse wildlife species make decision-making regarding restoration actions challenging. To address the challenge of spatial conservation prioritization, we developed the Prioritizing Restoration of Sagebrush Ecosystems Tool (PReSET). This decision support tool utilizes the prioritizr package in program R and an integer linear programming algorithm to select parcels representing both high biodiversity value and high probability of restoration success. We tested PReSET on a sagebrush steppe system within southwestern Wyoming using distributional data for six species with diverse life histories and a spatial layer of predicted sagebrush recovery times to identify restoration targets at both broad and local scales. While the broad-scale portion of our tool outputs can inform policy, the local-scale results can be applied directly to on-the-ground restoration. We identified restoration priority areas with greater precision than existing spatial prioritizations and incorporated range differences among species. We noted tradeoffs, including that restoring for habitat connectivity may require restoration actions in areas with lower probability of success. Future applications of PReSET will draw from emerging datasets, including spatially-varying economic costs of restoration, animal movement data, and additional species, to further improve our ability to target effective sagebrush restoration.

Published

2021

17. Synthesizing and analyzing long-term monitoring data: A greater sage-grouse case study

Author

Katherine S. Miller, Peter S. Coates, Steve E. Hanser, Michael A. Schroeder, Adrian P. Monroe, Kathleen A. Griffin, Julie A. Heinrichs, Travis J. Runia, Michael S. O'Donnell, David R. Edmunds, Thomas E. Remington, Leslie A. Schreiber, Nyssa I. Whitford, Jesse L. Kolar, Lief A. Wiechman, Shawn P. Espinosa, Avery A. Cook, Thomas J. Christiansen, Cameron L. Aldridge, Catherine S. Wightman, Ann M. Moser, Brian G. Prochazka, San J. Stiver, and Lee J. Foster

Subjects

0106 biological sciences, education.field_of_study, Ecology, Standardization, business.industry, Computer science, 010604 marine biology & hydrobiology, Applied Mathematics, Ecological Modeling, Data management, Population, Environmental resource management, Quality control, 010603 evolutionary biology, 01 natural sciences, Natural resource, Computer Science Applications, Terminology, Computational Theory and Mathematics, Modeling and Simulation, Informatics, business, education, Quality assurance, Ecology, Evolution, Behavior and Systematics

Abstract

Long-term monitoring of natural resources is imperative for increasing the understanding of ecosystem processes, services, and how to manage those ecosystems to maintain or improve function. Challenges with using these data may occur because methods of monitoring changed over time, multiple organizations collect and manage data differently, and monetary resources fluctuate, affecting many aspects of data. Because many species respond to changes in habitat conditions and predator-prey relationships across different spatial scales that span management boundaries, greater efforts for collaborating are essential. We demonstrate the challenges and methods for standardizing greater sage-grouse (Centrocercus urophasianus) long-term monitoring data across the species range in the western United States to inform population modeling needs identified by the Western Association of Fish and Wildlife Agencies. We used automated and repeatable methods of standardizing data via custom open-source software (grsg_lekdb) to improve the scientific integrity of future sage-grouse population assessments within and among states. Data standardization included reconciling uses of different terminology and expunging unusable data, resulting in the removal of 26% of data records due to database insertion errors and modifications to >1 million values to correct formatting and typing errors. Our approaches maximized the inclusion of usable data and identified data that could inform detection probabilities, population trends, and monitoring guidelines. Using sage-grouse databases as an example, we identified the importance of data management and how quality assurance and quality control measures can improve the usefulness of these data for future research needs. Our methods of using informatics and concluding recommendations can support similar endeavors of flora and fauna monitoring programs, whether those efforts are to use existing data or support new monitoring programs.

Published

2021

18. Greater sage‐grouse population trends across Wyoming

Author

Michael S. O'Donnell, Adrian P. Monroe, Cameron L. Aldridge, and David R. Edmunds

Subjects

0106 biological sciences, Generalized linear model, education.field_of_study, Ecology, Population, 010603 evolutionary biology, 01 natural sciences, 010601 ecology, Geography, Population viability analysis, General Earth and Planetary Sciences, Sage grouse, education, Ecology, Evolution, Behavior and Systematics, Nature and Landscape Conservation, General Environmental Science

Published

2017

19. Chronic wasting disease influences activity and behavior in white‐tailed deer

Author

Ronald G. Grogan, David E. Legg, Todd E. Cornish, Brant A. Schumaker, David R. Edmunds, Terry J. Kreeger, Shannon E. Albeke, Frederick G. Lindzey, and Walter E. Cook

Subjects

0106 biological sciences, animal diseases, Home range, Wildlife, Culling, Biology, Odocoileus, 010603 evolutionary biology, 01 natural sciences, medicine, Ecology, Evolution, Behavior and Systematics, Nature and Landscape Conservation, General Environmental Science, Riparian zone, geography, geography.geographical_feature_category, Ecology, Chronic wasting disease, medicine.disease, biology.organism_classification, 010601 ecology, Habitat, General Earth and Planetary Sciences, Biological dispersal, Demography

Abstract

Chronic wasting disease (CWD) is an infectious and fatal transmissible spongiform encephalopathy of members of the family Cervidae. Although CWD has been a serious concern among wildlife managers in several states in the United States and 2 Canadian provinces for over a decade, it is not known how CWD affects movement of hosts during the preclinical and clinical phases of disease. We hypothesized that normal movement patterns are altered by CWD. We evaluated migratory status, migration corridors, dispersal behavior, hourly activity patterns, home range areas, and resource selection for white-tailed deer (Odocoileus virginianus) of known CWD status as a means of understanding how CWD infection influenced habitat use and disease spread. We captured deer, tested for CWD by tonsil biopsy, marked deer with radio-transmitters (2003–2010) or global positioning system collars (2006–2010), and recaptured individuals annually for CWD testing. The proportion of CWD-positive females that migrated was significantly less than CWD-positive males. All deer that were CWD-negative were more active than their CWD-positive cohabitants, which was most pronounced in fall for males when CWD-positive deer were significantly less active throughout the day. Home range areas were small (x¯ = 1.99 km2) and were larger for CWD-negative females than CWD-positive females. Resource selection analyses indicated that all deer, regardless of CWD status, sex, or migratory status selected riparian habitats. Riparian habitats represent high CWD risk areas that should be targeted for potential disease management actions (e.g., surveillance, culling, environmental treatments). © 2017 The Wildlife Society.

Published

2017

20. Designing multi‐scale hierarchical monitoring frameworks for wildlife to support management: a sage‐grouse case study

Author

David R. Edmunds, Brian G. Prochazka, Cameron L. Aldridge, Julie A. Heinrichs, Steve E. Hanser, Michael S. O'Donnell, and Peter S. Coates

Subjects

Centrocercus urophasianus, hierarchically nested clusters, adaptive management, Ecology, Scale (ratio), business.industry, Computer science, graph theory, Environmental resource management, Wildlife, Adaptive management, lcsh:QH540-549.5, habitat connectivity, greater sage‐grouse, Sage grouse, lcsh:Ecology, business, Ecology, Evolution, Behavior and Systematics

Abstract

Population monitoring is integral to the conservation and management of wildlife; yet, analyses of population demographic data rarely consider processes occurring across spatial scales, potentially limiting the effectiveness of adaptive management. Therefore, we developed a method to identify hierarchical levels of organization (i.e., populations) to define multiple spatial scales, specifically intended to help guide appropriate conservation and management actions. This approach can support mobile species with high site fidelity where surveys occur on birthing/breeding grounds or migratory stopovers. Our approach used a graph‐based clustering algorithm (Spatial K'luster Analysis by Tree Edge Removal) that explicitly included habitat selection information at multiple scales and further refined with constraint‐based rules. We applied these concepts to greater sage‐grouse leks (breeding grounds), a species of conservation concern, in two different ecological contexts (Nevada and Wyoming, USA). The constraint‐based rules accounted for inter‐lek movement distances based on literature and field studies in Nevada from 2012 to 2016, included methods to support a spatially balanced monitoring design, and identified barriers to movements among leks based on resistance surfaces. We evaluated the performance of our hierarchical clusters in Nevada using independent data from radio‐marked sage‐grouse, and we found the finest‐scaled cluster level captured ~90% of sage‐grouse movements and mid‐level scales captured ~97–99% of movements. We expected comparable performance for Wyoming, where we lacked radio‐marked sage‐grouse for an evaluation, because genetic studies estimate similar dispersal distances to our ~15 km inter‐lek movement distance in Nevada. For sage‐grouse and other mobile species with high site fidelity, our approach to defining these frameworks could prove valuable for conservation and management applications, such as improving estimation of scale‐dependent population trends and guiding the prescription of management actions at spatial scales that align with identified threats. Specific to sage‐grouse, our analysis sets the stage for designing a monitoring framework that relies on comparison of short‐ and long‐term population trends across our defined spatial scales and identifies and disentangles factors driving local (e.g., habitat quality) and regional (e.g., climate) population changes, thereby supporting scale‐dependent management and research needs for adaptive management practices.

Published

2019

21. A review of chronic wasting disease in North America with implications for Europe

Author

Atle Mysterud and David R. Edmunds

Subjects

0106 biological sciences, education.field_of_study, Ecology, animal diseases, Population, Wildlife, Culling, Management, Monitoring, Policy and Law, Biology, Chronic wasting disease, medicine.disease, 010603 evolutionary biology, 01 natural sciences, Fencing, 010605 ornithology, law.invention, Transmission (mechanics), law, medicine, Keystone species, education, Ecology, Evolution, Behavior and Systematics, Epizootic, Nature and Landscape Conservation

Abstract

Cervids are keystone species in ecosystems and are associated with enormous cultural and economic value. Chronic wasting disease (CWD) is a fatal prion disease spreading in North American cervid populations. The 2016 emergence of CWD in Europe makes it urgent to understand the basics of CWD and to assess the extent to which current CWD knowledge is transferable to Europe. CWD is difficult to detect in the early stages due to very low prevalence and slow growth rates. The negative population effect of CWD is mainly due to increased female adult mortality, as infected individuals continue to reproduce. It may take decades before CWD leads to population declines. The population dynamics of mule deer are affected more by CWD than those of white-tailed deer, which in turn are more affected than those of elk, and depending on other factors limiting the populations. Species- and population-specific differences in dynamical consequences are linked to the balance among the rates of transmission, incubation period (linked to the prion protein gene, PRNP), and reproductive rates. This make it difficult to predict effects of CWD in Europe with other cervids, but the dynamic impact may be marked to cervid populations over the long term. The process of spillover across the species barrier is not well understood. Occasional spillover to moose without an apparent epizootic suggests specific conditions can limit CWD. Frequency-dependent transmission or weak density–dependent transmission makes it difficult to control CWD using density reductions through harvest and/or culling. CWD is difficult to eradicate once it becomes endemic, and it calls for immediate management actions. These actions involve extensive culling, fencing, and ceasing of wildlife feeding and are likely to cause significant controversy.

Published

2019

22. Effects of lek count protocols on greater sage-grouse population trend estimates

Author

Cameron L. Aldridge, Adrian P. Monroe, and David R. Edmunds

Subjects

0106 biological sciences, education.field_of_study, Ecology, Current distribution, Population size, Population, Diurnal temperature variation, 010603 evolutionary biology, 01 natural sciences, Sampling theory, 010601 ecology, Geography, Statistics, General Earth and Planetary Sciences, Sunrise, Sage grouse, education, Ecology, Evolution, Behavior and Systematics, Nature and Landscape Conservation, General Environmental Science, Count data

Abstract

Annual counts of males displaying at lek sites are an important tool for monitoring greater sage-grouse populations (Centrocercus urophasianus), but seasonal and diurnal variation in lek attendance may increase variance and bias of trend analyses. Recommendations for protocols to reduce observation error have called for restricting lek counts to within 30 minutes of sunrise, but this may limit the number of lek counts available for analysis, particularly from years before monitoring was widely standardized. Reducing the temporal window for conducting lek counts also may constrain the ability of agencies to monitor leks efficiently. We used lek count data collected across Wyoming during 1995−2014 to investigate the effect of lek counts conducted between 30 minutes before and 30, 60, or 90 minutes after sunrise on population trend estimates. We also evaluated trends across scales relevant to management, including statewide, within Working Group Areas and Core Areas, and for individual leks. To further evaluate accuracy and precision of trend estimates from lek count protocols, we used simulations based on a lek attendance model and compared simulated and estimated values of annual rate of change in population size (λ) from scenarios of varying numbers of leks, lek count timing, and count frequency (counts/lek/year). We found that restricting analyses to counts conducted within 30 minutes of sunrise generally did not improve precision of population trend estimates, although differences among timings increased as the number of leks and count frequency decreased. Lek attendance declined >30 minutes after sunrise, but simulations indicated that including lek counts conducted up to 90 minutes after sunrise can increase the number of leks monitored compared to trend estimates based on counts conducted within 30 minutes of sunrise. This increase in leks monitored resulted in greater precision of estimates without reducing accuracy. Increasing count frequency also improved precision. These results suggest that the current distribution of count timings available in lek count databases such as that of Wyoming (conducted up to 90 minutes after sunrise) can be used to estimate sage-grouse population trends without reducing precision or accuracy relative to trends from counts conducted within 30 minutes of sunrise. However, only 10% of all Wyoming counts in our sample (1995−2014) were conducted 61−90 minutes after sunrise, and further increasing this percentage may still bias trend estimates because of declining lek attendance. Published 2016. This article is a U.S. Government work and is in the public domain in the USA.

Published

2016

23. Hierarchical population monitoring of greater sage-grouse (Centrocercus urophasianus) in Nevada and California—Identifying populations for management at the appropriate spatial scale

Author

Kevin E. Doherty, David R. Edmunds, Michael S. O'Donnell, Mark A. Ricca, Shawn P. Espinosa, Peter S. Coates, Gregory T. Wann, Cameron L. Aldridge, Brian G. Prochazka, and Steven E. Hanser

Subjects

education.field_of_study, Geography, Ecology, Population, Spatial ecology, Sage grouse, education, Cartography

Published

2017

24. Chronic Wasting Disease Drives Population Decline of White-Tailed Deer

Author

Terry J. Kreeger, Todd E. Cornish, Walter E. Cook, Brant A. Schumaker, Fred Lindzey, David R. Edmunds, Ronald G. Grogan, and Matthew J. Kauffman

Subjects

0106 biological sciences, Male, Veterinary medicine, animal diseases, Maternal Health, Prevalence, lcsh:Medicine, Wildlife, 01 natural sciences, Population density, Animal Diseases, Prion Diseases, Pregnancy, Zoonoses, Epidemiology, Case fatality rate, Medicine and Health Sciences, lcsh:Science, Mammals, education.field_of_study, Multidisciplinary, Incidence (epidemiology), Obstetrics and Gynecology, Ruminants, 010601 ecology, Population decline, Animal Prion Diseases, Infectious Diseases, Veterinary Diseases, Fecundity, Vertebrates, Wasting Disease, Chronic, Female, Research Article, medicine.medical_specialty, Urology, Animal Types, Population, Equines, Animals, Wild, Biology, Mules, 010603 evolutionary biology, Population Metrics, medicine, Animals, Mortality, education, Population Growth, Population Density, Population Biology, Deer, lcsh:R, Organisms, Biology and Life Sciences, Chronic wasting disease, medicine.disease, Remote Sensing Technology, Amniotes, Women's Health, lcsh:Q, Veterinary Science, Zoology, Chronic Wasting Disease

Abstract

Chronic wasting disease (CWD) is an invariably fatal transmissible spongiform encephalopathy of white-tailed deer, mule deer, elk, and moose. Despite a 100% fatality rate, areas of high prevalence, and increasingly expanding geographic endemic areas, little is known about the population-level effects of CWD in deer. To investigate these effects, we tested the null hypothesis that high prevalence CWD did not negatively impact white-tailed deer population sustainability. The specific objectives of the study were to monitor CWD-positive and CWD-negative white-tailed deer in a high-prevalence CWD area longitudinally via radio-telemetry and global positioning system (GPS) collars. For the two populations, we determined the following: a) demographic and disease indices, b) annual survival, and c) finite rate of population growth (λ). The CWD prevalence was higher in females (42%) than males (28.8%) and hunter harvest and clinical CWD were the most frequent causes of mortality, with CWD-positive deer over-represented in harvest and total mortalities. Survival was significantly lower for CWD-positive deer and separately by sex; CWD-positive deer were 4.5 times more likely to die annually than CWD-negative deer while bucks were 1.7 times more likely to die than does. Population λ was 0.896 (0.859–0.980), which indicated a 10.4% annual decline. We show that a chronic disease that becomes endemic in wildlife populations has the potential to be population-limiting and the strong population-level effects of CWD suggest affected populations are not sustainable at high disease prevalence under current harvest levels.

Published

2016

25. Erratum

Author

Adrian P. Monroe, David R. Edmunds, Cameron L. Aldridge, and Michael S. O'Donnell

Subjects

0106 biological sciences, education.field_of_study, Ecology, Population, 010603 evolutionary biology, 01 natural sciences, 010601 ecology, Geography, General Earth and Planetary Sciences, Sage grouse, education, Ecology, Evolution, Behavior and Systematics, Nature and Landscape Conservation, General Environmental Science

Published

2018

26. Endemic chronic wasting disease causes mule deer population decline in Wyoming

Author

David R. Edmunds, Todd E. Cornish, Terry J. Kreeger, Bryan J. Richards, Brant A. Schumaker, Matthew J. Kauffman, Melia T. DeVivo, Hermann M. Schätzl, and Justin Binfet

Subjects

Male, Wyoming, 0301 basic medicine, Endemic Diseases, Maternal Health, animal diseases, Predation, lcsh:Medicine, Odocoileus, Population density, Geographical locations, Animal Diseases, Prion Diseases, 0403 veterinary science, Pregnancy, Zoonoses, Prevalence, Medicine and Health Sciences, lcsh:Science, Rocky Mountain elk, Mammals, education.field_of_study, Multidisciplinary, Ecology, Incidence (epidemiology), Eukaryota, Obstetrics and Gynecology, Ruminants, 04 agricultural and veterinary sciences, Trophic Interactions, Animal Prion Diseases, Population decline, Infectious Diseases, Community Ecology, Veterinary Diseases, Vertebrates, Wasting Disease, Chronic, Female, Research Article, 040301 veterinary sciences, Equines, Population, Zoology, Mules, Biology, 03 medical and health sciences, medicine, Animals, Population growth, education, Proportional Hazards Models, Population Density, Deer, Ecology and Environmental Sciences, lcsh:R, Organisms, Biology and Life Sciences, Chronic wasting disease, biology.organism_classification, medicine.disease, United States, 030104 developmental biology, Amniotes, North America, Women's Health, Veterinary Science, lcsh:Q, People and places, Chronic Wasting Disease

Abstract

Chronic wasting disease (CWD) is a fatal transmissible spongiform encephalopathy affecting white-tailed deer (Odocoileus virginianus), mule deer (Odocoileus hemionus), Rocky Mountain elk (Cervus elaphus nelsoni), and moose (Alces alces shirasi) in North America. In southeastern Wyoming average annual CWD prevalence in mule deer exceeds 20% and appears to contribute to regional population declines. We determined the effect of CWD on mule deer demography using age-specific, female-only, CWD transition matrix models to estimate the population growth rate (λ). Mule deer were captured from 2010–2014 in southern Converse County Wyoming, USA. Captured adult (≥ 1.5 years old) deer were tested ante-mortem for CWD using tonsil biopsies and monitored using radio telemetry. Mean annual survival rates of CWD-negative and CWD-positive deer were 0.76 and 0.32, respectively. Pregnancy and fawn recruitment were not observed to be influenced by CWD. We estimated λ = 0.79, indicating an annual population decline of 21% under current CWD prevalence levels. A model derived from the demography of only CWD-negative individuals yielded; λ = 1.00, indicating a stable population if CWD were absent. These findings support CWD as a significant contributor to mule deer population decline. Chronic wasting disease is difficult or impossible to eradicate with current tools, given significant environmental contamination, and at present our best recommendation for control of this disease is to minimize spread to new areas and naïve cervid populations.

Published

2017

27. Ocular plague (Yersinia pestis) in mule deer (Odocoileus hemionus) from Wyoming and Oregon

Author

Elizabeth S. Williams, David R. Edmunds, Paula T. Jaeger, Todd E. Cornish, Amy M. Boerger-Fields, Peggy L. Dearing, Donal O’Toole, Robert J. Bildfell, and Kenneth W. Mills

Subjects

Keratoconjunctivitis, Infectious, Male, Wyoming, Veterinary medicine, Pathology, medicine.medical_specialty, Yersinia pestis, animal diseases, Animals, Wild, Biology, Odocoileus, Eye, Bubonic plague, Ocular tissue, Oregon, Endophthalmitis, Fatal Outcome, medicine, Animals, Panophthalmitis, Ecology, Evolution, Behavior and Systematics, Keratoconjunctivitis, Plague, Ecology, Animal health, Deer, medicine.disease, biology.organism_classification, Female

Abstract

Although plague is relatively rare in wild ungulates, this report describes ocular lesions associated with Yersinia pestis infection in three free-ranging mule deer (Odocoileus hemionus) from Wyoming and Oregon, USA. All deer were observed antemortem and seemed to be blind. Post-mortem examination revealed gross lesions of bilateral keratoconjunctivitis and/or panophthalmitis in the first two deer, but only partial retinal detachment in the third deer. Microscopically, all deer had moderate-to-severe necrotizing and fibrinopurulent endophthalmitis and varying degrees of keratoconjunctivitis with abundant intralesional coccobacilli. The lesions in the first (D1) and third deer (D3) suggested an acute course, whereas those in the second deer (D2) were subacute to chronic. Yersinia pestis was isolated from ocular tissue swabs or ocular fluids of D1 and D2, and it was demonstrated by immunohistochemistry within ocular lesions of D1 and D3. Although plague does not seem to be a major cause of morbidity or mortality in free-ranging mule deer, keratoconjunctivitis or pinkeye is relatively common in these animals and plague should be considered as a differential diagnosis in such cases, with appropriate precautions taken to protect the human and animal health.

Published

2008

28. Endemic chronic wasting disease causes mule deer population decline in Wyoming.

Author

Melia T DeVivo, David R Edmunds, Matthew J Kauffman, Brant A Schumaker, Justin Binfet, Terry J Kreeger, Bryan J Richards, Hermann M Schätzl, and Todd E Cornish

Subjects

Medicine, Science

Abstract

Chronic wasting disease (CWD) is a fatal transmissible spongiform encephalopathy affecting white-tailed deer (Odocoileus virginianus), mule deer (Odocoileus hemionus), Rocky Mountain elk (Cervus elaphus nelsoni), and moose (Alces alces shirasi) in North America. In southeastern Wyoming average annual CWD prevalence in mule deer exceeds 20% and appears to contribute to regional population declines. We determined the effect of CWD on mule deer demography using age-specific, female-only, CWD transition matrix models to estimate the population growth rate (λ). Mule deer were captured from 2010-2014 in southern Converse County Wyoming, USA. Captured adult (≥ 1.5 years old) deer were tested ante-mortem for CWD using tonsil biopsies and monitored using radio telemetry. Mean annual survival rates of CWD-negative and CWD-positive deer were 0.76 and 0.32, respectively. Pregnancy and fawn recruitment were not observed to be influenced by CWD. We estimated λ = 0.79, indicating an annual population decline of 21% under current CWD prevalence levels. A model derived from the demography of only CWD-negative individuals yielded; λ = 1.00, indicating a stable population if CWD were absent. These findings support CWD as a significant contributor to mule deer population decline. Chronic wasting disease is difficult or impossible to eradicate with current tools, given significant environmental contamination, and at present our best recommendation for control of this disease is to minimize spread to new areas and naïve cervid populations.

Published

2017

29. Chronic Wasting Disease Drives Population Decline of White-Tailed Deer.

Author

David R Edmunds, Matthew J Kauffman, Brant A Schumaker, Frederick G Lindzey, Walter E Cook, Terry J Kreeger, Ronald G Grogan, and Todd E Cornish

Subjects

Medicine, Science

Abstract

Chronic wasting disease (CWD) is an invariably fatal transmissible spongiform encephalopathy of white-tailed deer, mule deer, elk, and moose. Despite a 100% fatality rate, areas of high prevalence, and increasingly expanding geographic endemic areas, little is known about the population-level effects of CWD in deer. To investigate these effects, we tested the null hypothesis that high prevalence CWD did not negatively impact white-tailed deer population sustainability. The specific objectives of the study were to monitor CWD-positive and CWD-negative white-tailed deer in a high-prevalence CWD area longitudinally via radio-telemetry and global positioning system (GPS) collars. For the two populations, we determined the following: a) demographic and disease indices, b) annual survival, and c) finite rate of population growth (λ). The CWD prevalence was higher in females (42%) than males (28.8%) and hunter harvest and clinical CWD were the most frequent causes of mortality, with CWD-positive deer over-represented in harvest and total mortalities. Survival was significantly lower for CWD-positive deer and separately by sex; CWD-positive deer were 4.5 times more likely to die annually than CWD-negative deer while bucks were 1.7 times more likely to die than does. Population λ was 0.896 (0.859-0.980), which indicated a 10.4% annual decline. We show that a chronic disease that becomes endemic in wildlife populations has the potential to be population-limiting and the strong population-level effects of CWD suggest affected populations are not sustainable at high disease prevalence under current harvest levels.

Published

2016