Dean Biggins, PhD
Dr. Biggins is a scientist emeritus at the Fort Collins Science Center.
Dr. Biggins has been interested in grassland ecology since 1981. Within that broad topic his research has involved varied themes, including aspects of behavioral ecology, predator-prey relationships, and ecology of wildlife diseases. Most of his investigations have been motivated by their application to conservation and recovery of federally listed species. In that context, Dr. Biggins has worked at field study sites from Montana to Chihuahua, Mexico, as well as in Inner Mongolia and the Tibetan Plateau. Research has involved students at various universities (in CA, CO, ID, NM, MI, MO, TX, WY, France, and China). Taxa of interest have been carnivores (e.g., black-footed ferrets, Siberian polecats, badgers, weasels, coyotes, foxes), rodents, arthropods (fleas, ticks), and bacteria (Yersinia pestis). His present research emphasis is on ecology of plague, including its hosts and vectors, concentrating on maintenance of plague and its chronic effects on wildlife populations and ecosystems during inter-epizootic periods.
Professional Experience
Scientist Emeritus, U.S. Geological Survey, 2019 - Present
Adjunct Faculty, Department of Biology, Colorado State University, 2002-present
Research Wildlife Biologist, U.S. Geological Survey, 1996-2019
Research Wildlife Biologist, National Biological Service, 1993-1996
Research Wildlife Biologist, U.S. Fish and Wildlife Service, 1976-1993
Education and Certifications
Ph.D., Zoology, Colorado State University, 2000
M.S., Wildlife Biology, University of Montana, 1975
B.S., Wildlife Management, Humboldt State University, 1968
Affiliations and Memberships*
American Society of Mammalogists, 1989 to present
Honors and Awards
2012—Aldo Leopold Award, American Society of Mammalogists
2005—Science Excellence Award of the Year, USGS, Biolo
2004—Conservationist of the Year, Denver Zoological Foundation
1998—Special Recognition Award, Black-footed Ferret Recovery Implementation Team
Science and Products
Comparison of flea sampling methods and Yersinia pestis detection on prairie dog colonies
Utah prairie dog population dynamics on the Awapa Plateau: Precipitation, elevation, and plague
Insect pathogenic fungi for biocontrol of plague vector fleas: A review
Plague transforms positive effects of precipitation on prairie dogs to negative effects
Fipronil pellets reduce flea abundance on black-tailed prairie dogs: Potential tool for plague management and black-footed ferret conservation
Epizootic plague in prairie dogs: Correlates and control with deltamethrin
Effects of experimental flea removal and plague vaccine treatments on survival of northern Idaho ground squirrels and two coexisting sciurids
Enzootic plague reduces survival of Mexican woodrats (Neotoma mexicana) in Colorado
Ecology and management of plague in diverse communities of rodents and fleas
Managing plague on prairie dog colonies: Insecticides as ectoparasiticides
Flea parasitism and host survival in a plague-relevant system: Theoretical and conservation implications
Flea sharing among sympatric rodent hosts: implications for potential plague effects on a threatened sciurid
Science and Products
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Comparison of flea sampling methods and Yersinia pestis detection on prairie dog colonies
Scientists collect fleas (Siphonaptera) to survey for Yersinia pestis, the bacterial agent of plague. When studying fleas parasitizing prairie dogs (Cynomys spp.), two primary methods are used: (1) combing fleas from live-trapped prairie dogs and (2) swabbing fleas from burrows with cloth swabs attached to metal cables. Ideally, burrow swabbing, the cheaper and easier method, would explain flea buAuthorsDavid A. Eads, Marc R. Matchett, Julia Poje, Dean E. BigginsUtah prairie dog population dynamics on the Awapa Plateau: Precipitation, elevation, and plague
Utah prairie dogs (UPDs, Cynomys parvidens) are colonial, herbivorous rodents listed under the Endangered Species Act as threatened. Little is known about UPD population dynamics at higher elevations in the species’ range. From 2013 through 2016, we studied UPDs on five colonies at 2,645 to 2,873 m elevation on the Awapa Plateau, Utah, USA. Primary production increases with precipitation and preciAuthorsDavid A. Eads, Dean E. BigginsInsect pathogenic fungi for biocontrol of plague vector fleas: A review
Bubonic plague is a lethal bacterial disease of great historical importance. The plague organism, Yersinia pestis, is primarily transmitted by fleas (Siphonaptera). In natural settings, where its range expands, Y. pestis resides in association with wild rodents and their fleas (sylvatic plague). While chemical insecticides are used against plague vector fleas, biological approaches have not been aAuthorsDavid A. Eads, Stefan Jaronski, Dean E. Biggins, Jeffrey WimsattPlague transforms positive effects of precipitation on prairie dogs to negative effects
Rodents characteristically benefit from increased precipitation, especially in typically dry habitats; “good years” of high precipitation improve their forage and water balance. However, Yersinia pestis (plague), a flea-borne pathogen of mammals that was introduced to western North America, has the greatest negative impact on at least some species of rodents during years of above-average precipitaAuthorsDean E. Biggins, David A. Eads, Jerry L. GodbeyFipronil pellets reduce flea abundance on black-tailed prairie dogs: Potential tool for plague management and black-footed ferret conservation
In western North America, sylvatic plague (a flea-borne disease) poses a significant risk to endangered black-footed ferrets (Mustela nigripes) and their primary prey, prairie dogs (Cynomys spp.). Pulicides (flea-killing agents) can be used to suppress fleas and thereby manage plague. In South Dakota, US, we tested edible “FipBit” pellets, each containing 0.84 mg fipronil, on free-living black-taiAuthorsDavid A. Eads, Travis M. Livieri, Phillip Dobesh, Eddie Childers, Lauren Noble, Michele Vasquez, Dean E. BigginsEpizootic plague in prairie dogs: Correlates and control with deltamethrin
The plague bacterium, Yersinia pestis, is a generalist pathogen of flea (Siphonaptera) vectors and mammalian hosts. In colonies of prairie dogs (PDs, Cynomys spp.), Y. pestis causes occasional epizootics, killing ≥90% of PDs within weeks to several months. We evaluated the effectiveness of deltamethrin, a pyrethroid insecticide, as a tool for preventing plague epizootics among three PD species. SpAuthorsDean E. Biggins, Jerry L. Godbey, David A. EadsEffects of experimental flea removal and plague vaccine treatments on survival of northern Idaho ground squirrels and two coexisting sciurids
Plague is a non-native disease in North America that reduces survival of many mammals. Previous studies have focused on epizootic plague which causes acute mortality events and dramatic declines in local abundance. We know much less about enzootic plague which causes less punctuated reductions in survival and abundance of infected populations. As a result, enzootic plague is much more difficult toAuthorsAmanda R. Goldberg, Courtney J. Conway, Dean E. BigginsEnzootic plague reduces survival of Mexican woodrats (Neotoma mexicana) in Colorado
Plague is a flea-vectored disease introduced to North America c. 1900. It is lethal to many American mammal species, causes major die-offs (epizootics) in some populations, and may be ecologically disruptive even at lower interepizootic (enzootic) levels of transmission. We sought to determine the effects of enzootic plague on survival of Mexican woodrats (Neotoma mexicana) and to test the hypotheAuthorsDean E. Biggins, Shantini Ramakrishnan, Tonie E. Rocke, Judy L. Williamson, Jeffrey WimsattEcology and management of plague in diverse communities of rodents and fleas
Plague originated in Asia as a flea-borne zoonosis of mammalian hosts. Today, the disease is distributed nearly worldwide. In western United States of America, plague is maintained, transmitted, and amplified in diverse communities of rodents and fleas. We examined flea diversity on three species of prairie dogs (Cynomys spp., PDs) and six species of sympatric small rodents in Montana and Utah, UnAuthorsDavid A. Eads, Dean E. Biggins, Kenneth L. GageManaging plague on prairie dog colonies: Insecticides as ectoparasiticides
Human health practitioners and wildlife biologists use insecticides to manage plague by suppressing fleas (Siphonaptera), but insecticides can also kill other ectoparasites. We investigated effects of deltamethrin and fipronil on ectoparasites from black-tailed prairie dogs (Cynomys ludovicianus, BTPDs). In late July, 2018, we treated three sites with 0.05% deltamethrin dust and 5 sites with host-AuthorsDavid A. Eads, Alexis Yashin, Lauren Nobel, Michele Vasquez, Miranda Huang, Travis M. Livieri, Phillip Dobesh, Eddie Childers, Dean E. BigginsFlea parasitism and host survival in a plague-relevant system: Theoretical and conservation implications
Plague is a bacterial zoonosis of mammalian hosts and flea vectors. The disease is capable of ravaging rodent populations and transforming ecosystems. Because plague mortality is likely to be predicted by flea parasitism, it is critical to understand vector dynamics. It has been hypothesized that paltry precipitation and reduced vegetative production predispose herbivorous rodents to malnourishmenAuthorsDavid A. Eads, Rachel C. Abbott, Dean E. Biggins, Tonie E. RockeFlea sharing among sympatric rodent hosts: implications for potential plague effects on a threatened sciurid
For vector-borne diseases, the abundance and competency of different vector species and their host preferences will impact the transfer of pathogens among hosts. Sylvatic plague is a lethal disease caused by the primarily flea-borne bacterium Yersinia pestis. Sylvatic plague was introduced into the western United States in the early 1900s and impacts many species of rodents. Plague may be suppressAuthorsAmanda R. Goldberg, Courtney J. Conway, Dean E. Biggins
*Disclaimer: Listing outside positions with professional scientific organizations on this Staff Profile are for informational purposes only and do not constitute an endorsement of those professional scientific organizations or their activities by the USGS, Department of the Interior, or U.S. Government