Probable causes of increasing brucellosis in free-ranging elk of the Greater Yellowstone Ecosystem.
about
Molecular epidemiology of Brucella abortus isolates from cattle, elk, and bison in the United States, 1998 to 2011Buffalo, bush meat, and the zoonotic threat of brucellosis in BotswanaGlobal positioning system data-loggers: a tool to quantify fine-scale movement of domestic animals to evaluate potential for zoonotic transmission to an endangered wildlife population.Detecting grizzly bear use of ungulate carcasses using global positioning system telemetry and activity data.Mapping brucellosis increases relative to elk density using hierarchical Bayesian models.Animal migration and infectious disease risk.Greater migratory propensity in hosts lowers pathogen transmission and impacts.Density-dependent effects on group size are sex-specific in a gregarious ungulate.Effects of goldfish (Carassius auratus) population size and body condition on the transmission of Gyrodactylus kobayashii (Monogenea).Modeling of wildlife-associated zoonoses: applications and caveatsGenomics reveals historic and contemporary transmission dynamics of a bacterial disease among wildlife and livestock.Managing more than the mean: using quantile regression to identify factors related to large elk groupsTransmission of brucellosis from elk to cattle and bison, Greater Yellowstone area, U.S.A., 2002-2012.Predicting Disease Risk, Identifying Stakeholders, and Informing Control Strategies: A Case Study of Anthrax in Montana.Environmental and behavioral changes may influence the exposure of an Arctic apex predator to pathogens and contaminantsAssembling evidence for identifying reservoirs of infection.Do irrigation and predator control reduce the productivity of migratory ungulate herds?Food for contagion: synthesis and future directions for studying host-parasite responses to resource shifts in anthropogenic environments.Responses of migratory species and their pathogens to supplemental feeding.Winter feeding of elk in the Greater Yellowstone Ecosystem and its effects on disease dynamics.Consistent individual differences and population plasticity in network-derived sociality: An experimental manipulation of density in a gregarious ungulate.Female elk contacts are neither frequency nor density dependent.Modeling vector-borne disease risk in migratory animals under climate change.Body condition and pregnancy in northern Yellowstone elk: evidence for predation risk effects?Rejoinder: challenge and opportunity in the study of ungulate migration amid environmental change.Costs and benefits of group living with disease: a case study of pneumonia in bighorn lambs (Ovis canadensis).Conservation management within strongholds in the face of disease-mediated invasions: red and grey squirrels as a case studyDisease emergence and invasionsInfluences of supplemental feeding on winter elk calf:cow ratios in the southern Greater Yellowstone EcosystemA multi-scale assessment of animal aggregation patterns to understand increasing pathogen seroprevalence
P2860
Q28730088-E354EEE4-CFFA-4FF4-938E-3A96DAEB9A6EQ28731418-632C587D-E968-4577-B8F0-56F1E2935193Q30866905-8EA5CD56-614D-405C-9B7E-D5F5B6C05861Q31057606-E9259D38-B372-412B-B12A-B4DAC5E134D2Q33567662-FE1BF75A-60DA-4D27-9F4B-0DEA00B713E8Q33798954-8F1480D8-CD29-4797-81ED-C0612B4483CAQ33954470-29D98D9C-6D85-4AED-8F3A-31B80C33C50EQ34551751-CB5F6F8E-8532-44A7-8642-D4888F885896Q36371318-B93326A0-B8A7-41CD-A868-D0C5F9D2C2F2Q36476820-9837D3AC-67B1-4A30-BF13-6CC3FFE72D57Q36898064-C5E019B7-459E-47F0-9383-B2D92D250B83Q37243395-60D6B6AA-3E6B-42CF-B2F9-3D56FF3C07C1Q37343695-12AB8B87-165A-480D-91C6-98E38D9F61DDQ40678479-97DF5C56-4568-451D-AAF9-2E2834287AD0Q42378923-9ADE1563-2803-4561-B343-6C1B022DABFAQ42550958-C783A8BD-E349-4F18-B994-A0EFA5630981Q44023746-2ABB0E86-E60A-416A-BACE-463C23937AAEQ51147982-B4A985F4-0F16-4148-9ACB-FA9B0BF19B29Q51148002-B4C582BF-0A12-4793-AB65-A853373E285BQ51148005-E4407CFE-B74D-4BEA-AEBC-815E5A77376AQ51150340-F6E23744-BEBB-42D4-8C7A-3E3E8F3AF703Q51182078-7621AA8D-537E-4AAE-9CBF-3B8BCC3B1E29Q51285872-175825D9-B6DC-4DE2-ABDF-D6301C730D08Q51471808-3D1AE298-4D49-4EF1-A7F1-EE66EBE1A8D2Q51517731-63EA8469-950A-46CC-9D9E-5250D52BE109Q51774308-8B6D2D1C-4B22-4325-9645-7FA01978B47BQ56444785-13394CBF-D653-46AF-A5B2-01DD23B89AC9Q56530197-8CFC8DF1-CD45-4511-BAE4-D06376172CE5Q57871527-FCF0E5FF-6C8C-4FA3-A5B3-D435344BF8E6Q57871534-9B6377E4-C996-41AB-8849-C859593CA022
P2860
Probable causes of increasing brucellosis in free-ranging elk of the Greater Yellowstone Ecosystem.
description
2010 nî lūn-bûn
@nan
2010年の論文
@ja
2010年学术文章
@wuu
2010年学术文章
@zh-cn
2010年学术文章
@zh-hans
2010年学术文章
@zh-my
2010年学术文章
@zh-sg
2010年學術文章
@yue
2010年學術文章
@zh
2010年學術文章
@zh-hant
name
Probable causes of increasing ...... Greater Yellowstone Ecosystem.
@en
Probable causes of increasing ...... Greater Yellowstone Ecosystem.
@nl
type
label
Probable causes of increasing ...... Greater Yellowstone Ecosystem.
@en
Probable causes of increasing ...... Greater Yellowstone Ecosystem.
@nl
prefLabel
Probable causes of increasing ...... Greater Yellowstone Ecosystem.
@en
Probable causes of increasing ...... Greater Yellowstone Ecosystem.
@nl
P2093
P2860
P356
P1476
Probable causes of increasing ...... Greater Yellowstone Ecosystem.
@en
P2093
Edwards WH
Middleton AD
Scurlock BM
P2860
P304
P356
10.1890/08-2062.1
P577
2010-01-01T00:00:00Z