Avian Influenza Research
Since Public Law 109-148, USGS has partnered with state and federal agencies to conduct science to support the national response to highly pathogenic avian influenza (HPAI). In 2014, the first reports of HPAI in US wild birds came from USGS cause-of-death investigations confirmed by the USDA.
Avian influenza is a global viral disease that is threatening wildlife, agriculture, and human health. Avian influenza viruses occur naturally in wild birds such as ducks, geese, swans, and gulls. The traditional view was that avian influenza viruses generally do not cause illness in wild birds, but they can become highly pathogenic, causing illness and death in backyard birds and commercial poultry. But during this current outbreak, highly pathogenic avian influenza has resulted in illness and death in wild birds and mammals in addition to infecting dairy cattle and other food animals
The USGS conducts research on avian influenza to understand its effects on wild bird populations and ecosystems. Leveraging ecological, genomic, and veterinary diagnostic data, USGS supports USDA’s national HPAI surveillance in wild birds and investigates the implications for wildlife health and biodiversity. The USGS Avian Influenza Science Team provides objective and rigorous scientific data for inferring:
- the utility of new methods to detect and characterize AIVs including those maintained in wildlife and the environment,
- impacts of HPAI to wildlife,
- spatiotemporal patterns of wildlife host and avian influenza virus dispersal, (iv) the occurrence and persistence of AIVs in the environment,
- how HPAI in wildlife influences consumptive and non-consumptive utilization of wildlife, (vi) how new tools and scientific methods may promote sound natural resource management decisions for HPAI in wildlife, particularly species of conservation concern, and
- the combined effects of HPAI and other stressors on ecosystem health and resiliency.
This research is crucial for informing wildlife management practices and public health policies, as avian influenza can also impact domestic poultry and pose risks to human health.
Following are a few significant contributions USGS science has made towards a better understanding of highly pathogenic avian influenza.
Agricultural Industry Support
By the end of 2015, losses associated with this highly pathogenic avian influenza outbreak exceeded 50 million poultry, resulting in over $3 billion dollars in economic impacts to the U.S. poultry industry.
In 2022, before the ongoing dairy cattle outbreak, a USGS study reviewed telemetry data (2015-2020) of wild migratory birds in California’s Central Valley. The results provided the first scientific evidence that wild birds (in this study, mallard, northern pintail, and cinnamon teal) do go onto dairy and poultry operations.
USGS scientists studied wild bird use of retention ponds on poultry operations in the Delmarva Peninsula on the East Coast. Using six months of data, they found that several wild bird species used retention ponds. While more research is needed, the study resulted in two key findings: (1) Temporal trends aligned with migratory pulses in local wild bird abundance and (2) wild bird use appeared to be related to vegetation surrounding ponds. Most waterfowl preferred open habitat with sparse vegetation except for wood ducks that preferred tree-dominated sites. This suggests that vegetation management might help reduce the risk of avian influenza spread through this interface.
USGS risk assessment tools and mathematical modeling framework for the wild bird-poultry interface were used by the USDA in the early HPAI response in 2022 to identify spillover risk from wild bird to poultry, helping safeguard the $240-billion U.S. poultry industry from economic losses.
![Canada Geese in Front of a Poultry House](https://d9-wret.s3.us-west-2.amazonaws.com/assets/palladium/production/s3fs-public/styles/full_width/public/media/images/CanadaGeeseOnPond_Crop.png?itok=P0v25CI6)
Disease Surveillance
- For wild bird cause-of-death investigations, the USGS National Wildlife Health Center routinely tests samples from wild birds for avian influenza viruses. The USDA recognizes the USGS National Wildlife Health Center, which has conducted wild bird cause-of-death investigations since 1975, as their “primary partner for performing diagnostics related to [wild bird] morbidity/mortality events.” In fact, the 2014 first reports of HPAI in U.S. wild birds resulted from NWHC diagnostics confirmed by USDA (publication). trace
- USGS Eastern Ecological Science Center diving duck HPAI science, in collaboration with the USDA, led to revision of the USDA's list of wild bird species in their national HPAI surveillance plan. The USDA regularly collaborates with USGS Alaska Science Center for wild bird HPAI surveillance, viral genomics, and HPAI traceback investigations due to strong local partnerships there and long-term avian influenza surveillance and ecological research at Izembek National Wildlife Refuge, a wetland of international importance. Notably, USGS science identified multiple introductions of HPAI into Alaska from Asia during the current outbreak as well as evidence for viral spread between wild birds, domestic poultry, and wild mammals in Alaska.
![USGS biologists swab a hen mallard duck for avian influenza](https://d9-wret.s3.us-west-2.amazonaws.com/assets/palladium/production/s3fs-public/styles/full_width/public/media/images/Mallard%20Swabbing.jpg?itok=fVPEA9S2)
Environmental Persistence
- After determining that HPAI viruses can persist in natural surface waters, the USGS collaborated with the Center for Disease Control to operationalize water surveillance, identifying infectious HPAI in four Iowa wetlands. USGS scientists are now working with the U.S. Fish and Wildlife Service to understand the potential of using water manipulation to reduce HPAI in the environment.
![Wildlife and Agricultural Wetlands](https://d9-wret.s3.us-west-2.amazonaws.com/assets/palladium/production/s3fs-public/styles/full_width/public/100_0316a.jpg?itok=-JsMfj7Q)
Utilization of HPAI Vaccines in Wildlife
- In spring 2023, an HPAI outbreak began affecting California condors, mobilizing USGS wildlife vaccine experts to collaborate with USFWS and USDA to evaluate the safety and immunogenicity of a poultry HPAI vaccine for critically endangered California condors. A surrogate species (Black Vultures, Coragyps atratus) was utilized for initial vaccine trials, which were successful. Subsequently, a trial with captive California Condors was conducted with no serious adverse reactions and good immunological responses. Based on these results, a two-dose vaccination protocol was initiated for free-flying California condors.
![California Condor](https://d9-wret.s3.us-west-2.amazonaws.com/assets/palladium/production/s3fs-public/styles/full_width/public/CA_condor_dsc03775_Sue_Haig_photo.jpg?itok=FBHpJ5SF)
Advancing Risk Modeling for Highly Pathogenic Avian Influenza
Highly Pathogenic Avian Influenza Seaduck Challenge Study
Avian Influenza Research
Avian Influenza Surveillance
Understanding Avian Influenza Infection and Movement Behavior of Wild Waterfowl
Understanding wild waterfowl use of retention ponds at commercial poultry farms – a potential route for avian influenza virus transmission
Q&A: Bird Flu - Ongoing Threat of Highly Pathogenic Avian Influenza (HPAI) in Alaska and North America
Environmental detection of avian influenza virus
Avian Influenza Dynamics in the Chesapeake Bay Region
Understanding the environmental pathways of avian influenza transmission
Distribution of Highly Pathogenic Avian Influenza in North America, 2021/2022
Avian Influenza Prevalence Correlated to Mercury Concentrations in Wild Waterfowl
Data on Exposure of Wild Mammals Inhabiting Alaska to H5N1 Influenza A Viruses
Solutions and extended results for laboratory tests used in the development of a large volume concentration method to recover infectious avian influenza virus from the aquatic environment, 2022
Data describing the lack of Avian influenza infection and antibodies in Eastern Wild Turkeys (Meleagris gallopavo silvestris) sampled in Delmarva, USA
Estimates of avian influenza transmission risk across the wild waterfowl - domestic poultry interface (ver. 2.0, May 2024)
Data for Genomic Characterization of Highly Pathogenic H5 Avian Influenza Viruses from Alaska in 2022
Data describing highly pathogenic H5N1 in Double-crested Cormorants of the Chesapeake Bay (ver. 2.0, December 2024)
Timing of Occurrence of Waterfowl in U.S. Counties and Canadian Counties, Boroughs, Census Districts, and Other Populated Area Designations with Modeled Exposure Status to Highly Pathogenic Avian Influenza Virus in 2021-2022
Dataset: Sero-surveillance for avian influenza exposure in wild birds in Iceland, 2012-2017
Database collating previous laboratory investigations into the pathogenesis of avian influenza viruses in wild avifauna of North America (ver. 2.0, August 2024)
Sampling information and water-quality data collected during viable avian influenza virus sampling in Iowa wetlands, 2022
Molecular Detection and Characterization of Highly Pathogenic H5N1 Avian Influenza Viruses in Wild Birds Inhabiting Western Alaska Provides Evidence for Three Independent Viral Introductions
Data showing similar movement ecology between mallards infected and not infected with highly pathogenic avian influenza H5N1
Development of a large-volume concentration method to recover infectious avian influenza virus from the aquatic environment
Influenza A virus antibodies in ducks and introduction of highly pathogenic influenza A(H5N1) virus, Tennessee, USA
Genotypic clustering of H5N1 avian Influenza viruses in North America evaluated by ordination analysis
A systematic review of laboratory investigations into the pathogenesis of avian influenza viruses in wild avifauna of North America
Genomic characterization of highly pathogenic H5 avian influenza viruses from Alaska during 2022 provides evidence for genotype-specific trends of spatiotemporal and interspecies dissemination
Mitigating risk: Predicting H5N1 avian influenza spread with an empirical model of bird movement
Sero-epidemiology of Highly Pathogenic Avian Influenza viruses among wild birds in subarctic intercontinental transition zones
Using an adaptive modeling framework to identify avian influenza spillover risk at the wild-domestic interface
Highly pathogenic avian influenza A(H5N1) virus clade 2.3.4.4b infections in wild terrestrial mammals, United States, 2022
Climate change impacts on bird migration and highly pathogenic avian influenza
Environmental surveillance and detection of infectious highly pathogenic avian influenza virus in Iowa wetlands
Molecular detection and characterization of highly pathogenic H5N1 clade 2.3.4.4b avian influenza viruses among hunter-harvested wild birds provides evidence for three independent introductions into Alaska
Avian Influenza: Research by the USGS and Partners
Story Map: Avian Influenza in the United States
Wildlife Health Information Sharing Partnership – event reporting system (WHISPers)
Visualizing Models for Avian Influenza Viruses
For more information about avian influenza, explore our Frequently Asked Questions.
What is Avian Influenza?
What are the different types of avian influenza?
What is the meaning of the numbers next to the “H” and “N” in avian influenza designations?
What is the difference between low pathogenic and highly pathogenic avian influenza?
Can wild birds spread avian influenza to domestic poultry?
Can people get avian influenza?
How do scientists study avian influenza in wild birds?
How is avian influenza spread?
Since Public Law 109-148, USGS has partnered with state and federal agencies to conduct science to support the national response to highly pathogenic avian influenza (HPAI). In 2014, the first reports of HPAI in US wild birds came from USGS cause-of-death investigations confirmed by the USDA.
Avian influenza is a global viral disease that is threatening wildlife, agriculture, and human health. Avian influenza viruses occur naturally in wild birds such as ducks, geese, swans, and gulls. The traditional view was that avian influenza viruses generally do not cause illness in wild birds, but they can become highly pathogenic, causing illness and death in backyard birds and commercial poultry. But during this current outbreak, highly pathogenic avian influenza has resulted in illness and death in wild birds and mammals in addition to infecting dairy cattle and other food animals
The USGS conducts research on avian influenza to understand its effects on wild bird populations and ecosystems. Leveraging ecological, genomic, and veterinary diagnostic data, USGS supports USDA’s national HPAI surveillance in wild birds and investigates the implications for wildlife health and biodiversity. The USGS Avian Influenza Science Team provides objective and rigorous scientific data for inferring:
- the utility of new methods to detect and characterize AIVs including those maintained in wildlife and the environment,
- impacts of HPAI to wildlife,
- spatiotemporal patterns of wildlife host and avian influenza virus dispersal, (iv) the occurrence and persistence of AIVs in the environment,
- how HPAI in wildlife influences consumptive and non-consumptive utilization of wildlife, (vi) how new tools and scientific methods may promote sound natural resource management decisions for HPAI in wildlife, particularly species of conservation concern, and
- the combined effects of HPAI and other stressors on ecosystem health and resiliency.
This research is crucial for informing wildlife management practices and public health policies, as avian influenza can also impact domestic poultry and pose risks to human health.
Following are a few significant contributions USGS science has made towards a better understanding of highly pathogenic avian influenza.
Agricultural Industry Support
By the end of 2015, losses associated with this highly pathogenic avian influenza outbreak exceeded 50 million poultry, resulting in over $3 billion dollars in economic impacts to the U.S. poultry industry.
In 2022, before the ongoing dairy cattle outbreak, a USGS study reviewed telemetry data (2015-2020) of wild migratory birds in California’s Central Valley. The results provided the first scientific evidence that wild birds (in this study, mallard, northern pintail, and cinnamon teal) do go onto dairy and poultry operations.
USGS scientists studied wild bird use of retention ponds on poultry operations in the Delmarva Peninsula on the East Coast. Using six months of data, they found that several wild bird species used retention ponds. While more research is needed, the study resulted in two key findings: (1) Temporal trends aligned with migratory pulses in local wild bird abundance and (2) wild bird use appeared to be related to vegetation surrounding ponds. Most waterfowl preferred open habitat with sparse vegetation except for wood ducks that preferred tree-dominated sites. This suggests that vegetation management might help reduce the risk of avian influenza spread through this interface.
USGS risk assessment tools and mathematical modeling framework for the wild bird-poultry interface were used by the USDA in the early HPAI response in 2022 to identify spillover risk from wild bird to poultry, helping safeguard the $240-billion U.S. poultry industry from economic losses.
![Canada Geese in Front of a Poultry House](https://d9-wret.s3.us-west-2.amazonaws.com/assets/palladium/production/s3fs-public/styles/full_width/public/media/images/CanadaGeeseOnPond_Crop.png?itok=P0v25CI6)
Disease Surveillance
- For wild bird cause-of-death investigations, the USGS National Wildlife Health Center routinely tests samples from wild birds for avian influenza viruses. The USDA recognizes the USGS National Wildlife Health Center, which has conducted wild bird cause-of-death investigations since 1975, as their “primary partner for performing diagnostics related to [wild bird] morbidity/mortality events.” In fact, the 2014 first reports of HPAI in U.S. wild birds resulted from NWHC diagnostics confirmed by USDA (publication). trace
- USGS Eastern Ecological Science Center diving duck HPAI science, in collaboration with the USDA, led to revision of the USDA's list of wild bird species in their national HPAI surveillance plan. The USDA regularly collaborates with USGS Alaska Science Center for wild bird HPAI surveillance, viral genomics, and HPAI traceback investigations due to strong local partnerships there and long-term avian influenza surveillance and ecological research at Izembek National Wildlife Refuge, a wetland of international importance. Notably, USGS science identified multiple introductions of HPAI into Alaska from Asia during the current outbreak as well as evidence for viral spread between wild birds, domestic poultry, and wild mammals in Alaska.
![USGS biologists swab a hen mallard duck for avian influenza](https://d9-wret.s3.us-west-2.amazonaws.com/assets/palladium/production/s3fs-public/styles/full_width/public/media/images/Mallard%20Swabbing.jpg?itok=fVPEA9S2)
Environmental Persistence
- After determining that HPAI viruses can persist in natural surface waters, the USGS collaborated with the Center for Disease Control to operationalize water surveillance, identifying infectious HPAI in four Iowa wetlands. USGS scientists are now working with the U.S. Fish and Wildlife Service to understand the potential of using water manipulation to reduce HPAI in the environment.
![Wildlife and Agricultural Wetlands](https://d9-wret.s3.us-west-2.amazonaws.com/assets/palladium/production/s3fs-public/styles/full_width/public/100_0316a.jpg?itok=-JsMfj7Q)
Utilization of HPAI Vaccines in Wildlife
- In spring 2023, an HPAI outbreak began affecting California condors, mobilizing USGS wildlife vaccine experts to collaborate with USFWS and USDA to evaluate the safety and immunogenicity of a poultry HPAI vaccine for critically endangered California condors. A surrogate species (Black Vultures, Coragyps atratus) was utilized for initial vaccine trials, which were successful. Subsequently, a trial with captive California Condors was conducted with no serious adverse reactions and good immunological responses. Based on these results, a two-dose vaccination protocol was initiated for free-flying California condors.
![California Condor](https://d9-wret.s3.us-west-2.amazonaws.com/assets/palladium/production/s3fs-public/styles/full_width/public/CA_condor_dsc03775_Sue_Haig_photo.jpg?itok=FBHpJ5SF)
Advancing Risk Modeling for Highly Pathogenic Avian Influenza
Highly Pathogenic Avian Influenza Seaduck Challenge Study
Avian Influenza Research
Avian Influenza Surveillance
Understanding Avian Influenza Infection and Movement Behavior of Wild Waterfowl
Understanding wild waterfowl use of retention ponds at commercial poultry farms – a potential route for avian influenza virus transmission
Q&A: Bird Flu - Ongoing Threat of Highly Pathogenic Avian Influenza (HPAI) in Alaska and North America
Environmental detection of avian influenza virus
Avian Influenza Dynamics in the Chesapeake Bay Region
Understanding the environmental pathways of avian influenza transmission
Distribution of Highly Pathogenic Avian Influenza in North America, 2021/2022
Avian Influenza Prevalence Correlated to Mercury Concentrations in Wild Waterfowl
Data on Exposure of Wild Mammals Inhabiting Alaska to H5N1 Influenza A Viruses
Solutions and extended results for laboratory tests used in the development of a large volume concentration method to recover infectious avian influenza virus from the aquatic environment, 2022
Data describing the lack of Avian influenza infection and antibodies in Eastern Wild Turkeys (Meleagris gallopavo silvestris) sampled in Delmarva, USA
Estimates of avian influenza transmission risk across the wild waterfowl - domestic poultry interface (ver. 2.0, May 2024)
Data for Genomic Characterization of Highly Pathogenic H5 Avian Influenza Viruses from Alaska in 2022
Data describing highly pathogenic H5N1 in Double-crested Cormorants of the Chesapeake Bay (ver. 2.0, December 2024)
Timing of Occurrence of Waterfowl in U.S. Counties and Canadian Counties, Boroughs, Census Districts, and Other Populated Area Designations with Modeled Exposure Status to Highly Pathogenic Avian Influenza Virus in 2021-2022
Dataset: Sero-surveillance for avian influenza exposure in wild birds in Iceland, 2012-2017
Database collating previous laboratory investigations into the pathogenesis of avian influenza viruses in wild avifauna of North America (ver. 2.0, August 2024)
Sampling information and water-quality data collected during viable avian influenza virus sampling in Iowa wetlands, 2022
Molecular Detection and Characterization of Highly Pathogenic H5N1 Avian Influenza Viruses in Wild Birds Inhabiting Western Alaska Provides Evidence for Three Independent Viral Introductions
Data showing similar movement ecology between mallards infected and not infected with highly pathogenic avian influenza H5N1
Development of a large-volume concentration method to recover infectious avian influenza virus from the aquatic environment
Influenza A virus antibodies in ducks and introduction of highly pathogenic influenza A(H5N1) virus, Tennessee, USA
Genotypic clustering of H5N1 avian Influenza viruses in North America evaluated by ordination analysis
A systematic review of laboratory investigations into the pathogenesis of avian influenza viruses in wild avifauna of North America
Genomic characterization of highly pathogenic H5 avian influenza viruses from Alaska during 2022 provides evidence for genotype-specific trends of spatiotemporal and interspecies dissemination
Mitigating risk: Predicting H5N1 avian influenza spread with an empirical model of bird movement
Sero-epidemiology of Highly Pathogenic Avian Influenza viruses among wild birds in subarctic intercontinental transition zones
Using an adaptive modeling framework to identify avian influenza spillover risk at the wild-domestic interface
Highly pathogenic avian influenza A(H5N1) virus clade 2.3.4.4b infections in wild terrestrial mammals, United States, 2022
Climate change impacts on bird migration and highly pathogenic avian influenza
Environmental surveillance and detection of infectious highly pathogenic avian influenza virus in Iowa wetlands
Molecular detection and characterization of highly pathogenic H5N1 clade 2.3.4.4b avian influenza viruses among hunter-harvested wild birds provides evidence for three independent introductions into Alaska
Avian Influenza: Research by the USGS and Partners
Story Map: Avian Influenza in the United States
Wildlife Health Information Sharing Partnership – event reporting system (WHISPers)
Visualizing Models for Avian Influenza Viruses
For more information about avian influenza, explore our Frequently Asked Questions.