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Influenza A virus
Colorized transmission electron micrograph of Avian influenza A H5N1 viruses (seen in gold) grown in MDCK cells (seen in green)
Virus classification
(unranked):	Virus
Realm:	Riboviria
Kingdom:	Orthornavirae
Phylum:	Negarnaviricota
Class:	Insthoviricetes
Order:	Articulavirales
Family:	Orthomyxoviridae
Genus:	Alphainfluenzavirus
Species:	Influenza A virus
Notable strains
Goose Guangdong virus A/Fujian (H5N1)

Influenza A virus subtype H5N1 (A/H5N1) is a subtype of the influenza A virus, which causes the disease avian influenza (often referred to as "bird flu"). It is enzootic (maintained in the population) in many bird populations, and also panzootic (affecting animals of many species over a wide area).^[1] A/H5N1 virus can also infect mammals (including humans) that have been exposed to infected birds; in these cases, symptoms are frequently severe or fatal.^[2]

A/H5N1 virus is shed in the saliva, mucus, and feces of infected birds; other infected animals may shed bird flu viruses in respiratory secretions and other body fluids (such as milk).^[3] The virus can spread rapidly through poultry flocks and among wild birds.^[3] An estimated half billion farmed birds have been slaughtered in efforts to contain the virus.^[2]

Symptoms of A/H5N1 influenza vary according to both the strain of virus underlying the infection and on the species of bird or mammal affected.^[4][5] Classification as either Low Pathogenic Avian Influenza (LPAI) or High Pathogenic Avian Influenza (HPAI) is based on the severity of symptoms in domestic chickens and does not predict the severity of symptoms in other species.^[6] Chickens infected with LPAI A/H5N1 virus display mild symptoms or are asymptomatic, whereas HPAI A/H5N1 causes serious breathing difficulties, a significant drop in egg production, and sudden death.^[7]

In mammals, including humans, A/H5N1 influenza (whether LPAI or HPAI) is rare. Symptoms of infection vary from mild to severe, including fever, diarrhea, and cough.^[5] Human infections with A/H5N1 virus have been reported in 23 countries since 1997, resulting in severe pneumonia and death in about 50% of cases.^[8] Between 2003 and February 2025, the World Health Organization has recorded 972 cases of confirmed H5N1 influenza, leading to 468 deaths.^[9] The true fatality rate may be lower because some cases with mild symptoms may not have been identified as H5N1.^[10]

A/H5N1 influenza virus was first identified in farmed birds in southern China in 1996.^[11] Between 1996 and 2018, A/H5N1 coexisted in bird populations with other subtypes of the virus, but since then, the highly pathogenic subtype HPAI A(H5N1) has become the dominant strain in bird populations worldwide.^[12] Some strains of A/H5N1 which are highly pathogenic to chickens have adapted to cause mild symptoms in ducks and geese,^[13][6] and are able to spread rapidly through bird migration.^[14] Mammal species in addition to humans that have been recorded with H5N1 infection include cattle, seals, goats, and skunks.^[15]

Due to the high lethality and virulence of HPAI A(H5N1), its worldwide presence, its increasingly diverse host reservoir, and its significant ongoing mutations, the H5N1 virus is regarded as the world's largest pandemic threat.^[16] Domestic poultry may potentially be protected from specific strains of the virus by vaccination.^[17] In the event of a serious outbreak of H5N1 flu among humans, health agencies have prepared "candidate" vaccines that may be used to prevent infection and control the outbreak; however, it could take several months to ramp up mass production.^[3][18][19]

Avian flu viruses, both HPAI and LPAI, can infect humans who are in close, unprotected contact with infected poultry. Incidents of cross-species transmission are rare, with symptoms ranging in severity from no symptoms or mild illness, to severe disease that resulted in death.^[22][23] As of February 2024 there have been very few instances of human-to-human transmission, and each outbreak has been limited to a few people.^[24] All subtypes of avian Influenza A have potential to cross the species barrier, with H5N1 and H7N9 considered the biggest threats.^[25][26] In December 2024, researchers showed one mutation could allow the virus to switch its specificity to human receptors,^[27] increasing the risk of human-to-human transmission.

In order to avoid infection, the general public are advised to avoid contact with sick birds or potentially contaminated material such as carcasses or feces. People working with birds, such as conservationists or poultry workers, are advised to wear appropriate personal protection equipment.^[28]

The avian influenza hemagglutinin prefers to bind to alpha-2,3 sialic acid receptors, while the human influenza hemagglutinin prefers to bind to alpha-2,6 sialic acid receptors.^[29][30] This means that when the H5N1 strain infects humans, it will replicate in the lower respiratory tract (where alpha-2,3 sialic acid receptors are more plentiful in humans) and consequently cause viral pneumonia.^[31][32]

Between 2003 and February 2025, the World Health Organization has recorded 972 cases of confirmed H5N1 influenza, leading to 468 deaths.^[33] The true fatality rate may be lower because some cases with mild symptoms may not have been identified as H5N1.^[10]

On January 6, 2025, the first death from avian influenza in the United States was recorded. This was the first case considered to officially link transmission of avian influenza to backyard flocks. The individual was reported to have been older than 65, had underlying medical problems as well as being in contact with multiple sick and dead birds from their backyard flock.^[34]

To unambiguously describe a specific isolate of virus, researchers use the internationally accepted Influenza virus nomenclature,^[35] which describes, among other things, the species of animal from which the virus was isolated, and the place and year of collection. For example, A/chicken/Nakorn-Patom/Thailand/CU-K2/04(H5N1):

• A stands for the genus of influenza (A, B or C)
• chicken is the animal species the isolate was found in (note: human isolates lack this component term and are thus identified as human isolates by default)
• Nakorn-Patom/Thailand is the place this specific virus was isolated
• CU-K2 is the laboratory reference number that identifies it from other influenza viruses isolated at the same place and year
• 04 represents the year of isolation 2004
• H5 stands for the fifth of several known types of the protein hemagglutinin
• N1 stands for the first of several known types of the protein neuraminidase.

Other examples include: A/duck/Hong Kong/308/78(H5N3), and A/shoveler/Egypt/03(H5N2).^[36]

H5N1 is a subtype of Influenza A virus. Like all subtypes it is an enveloped negative-sense RNA virus, with a segmented genome.^[37] Subtypes of IAV are defined by the combination of the antigenic hemagglutinin and neuraminidase proteins in the viral envelope. "H5N1" designates an IAV subtype that has a type 5 hemagglutinin (H) protein and a type-1 neuraminidase (N) protein.^[38] Further variations exist within the subtypes and can lead to very significant differences in the virus's ability to infect and cause disease, as well as to the severity of symptoms.^[39][40]

Influenza viruses have a relatively high mutation rate that is characteristic of RNA viruses.^[41] The segmentation of its genome facilitates genetic recombination by segment reassortment in hosts infected with two different strains of influenza viruses at the same time.^[42][43] Through a combination of mutation and genetic reassortment the virus can evolve to acquire new characteristics, enabling it to evade host immunity and occasionally to jump from one species of host to another.^[44][45]

Humans – Several "candidate" (unproved) vaccines are available in case an avian virus acquires the ability to infect and transmit among humans; as of July 2024 these include Aflunov, Celldemic and Seqirus/Audenz.^[46][47] Some governments have prepared strategic stockpiles of vaccines against the H5N1 subtype which is considered the biggest risk among subtypes.^[48][49][47] However, because the influenza virus is highly variable, any vaccine needs to be specifically targeted against the particular strain of virus which is causing concern. Existing influenza vaccine technologies can be adapted to a H5N1 strain causing the pandemic; in the event of an outbreak, the candidate vaccine would be rapidly tested for safety as well as efficacy against the zoonotic strain, and then authorised and distributed to vaccine manufacturers.^[50][46]

Poultry – it is possible to vaccinate poultry against specific strains of HPAI influenza. Vaccination should be combined with other control measures such as infection monitoring, early detection and biosecurity.^[51][52] In many countries, it is routine to vaccinate poultry against H5N1.^[53] In China, the world's biggest poultry producer, there has been is a mandatory vaccination requirement since 2017; the vaccine is bivalent or trivalent, targeting the H5 and H7 subtypes of influenza A virus. It is manufactured using recombinant influenza virus.^[54]

In the event of an outbreak of human H5N1, the main antiviral drugs recommended are neuraminidase inhibitors, such as zanamivir (Relenza) and oseltamivir (Tamiflu). These drugs can reduce the severity of symptoms if taken soon after infection and can also be taken as prophylaxis to decrease the risk of infection.^{[55][56][57][58]}

Influenza A/H5N1 was first detected in 1959 after an outbreak of highly pathogenic avian influenza in Scotland, which infected two flocks of chickens.^[59][60] The next detection, and the earliest infection of humans by H5N1, was an epizootic (an epidemic in nonhumans) of H5N1 influenza in Hong Kong's poultry population in 1997. This outbreak was stopped by the killing of the entire domestic poultry population within the territory. Human infection was confirmed in 18 individuals who had been in close contact with poultry, 6 of whom died.^[61][62]

Since then, avian A/H5N1 bird flu has become widespread in wild birds worldwide, with numerous outbreaks among both domestic and wild birds. An estimated half a billion farmed birds have been slaughtered in efforts to contain the virus.^[63][64]

Influenza viruses have a relatively high mutation rate that is characteristic of RNA viruses.^[65] The segmentation of the influenza A virus genome facilitates genetic recombination by segment reassortment in hosts who become infected with two different strains of influenza viruses at the same time.^[42][66] With reassortment between strains, an avian strain which does not affect humans may acquire characteristics from a different strain which enable it to infect and pass between humans – a zoonotic event.^[67]

As of June 2024, there is concern about two subtypes of avian influenza which are circulating in wild bird populations worldwide, A/H5N1 and A/H7N9. Both of these have potential to devastate poultry stocks, and both have jumped to humans with relatively high case fatality rates.^[68] A/H5N1 in particular has infected a wide range of mammals and may be adapting to mammalian hosts.^[69]

The Global Influenza Surveillance and Response System (GISRS) is a global network of laboratories that monitor the spread of influenza with the aim to provide the World Health Organization with influenza control information and to inform vaccine development.^[70] Several millions of specimens are tested by the GISRS network annually through a network of laboratories in 127 countries. GISRS monitors avian, swine, and other potentially zoonotic influenza viruses as well as human viruses.^[71]

Birds – Influenza A viruses of various subtypes have a large reservoir in wild waterfowl, which can infect the respiratory and gastrointestinal tract without affecting the health of the host. They can then be carried by the bird over large distances especially during annual migration. Infected birds can shed avian influenza A viruses in their saliva, nasal secretions, and feces; susceptible birds become infected when they have contact with the virus as it is shed by infected birds.^[73] The virus can survive for long periods in water and at low temperatures, and can be spread from one farm to another on farm equipment.^[74] Domesticated birds (chickens, turkeys, ducks, etc.) may become infected with avian influenza A viruses through direct contact with infected waterfowl or other infected poultry, or through contact with contaminated feces or surfaces.

Avian influenza outbreaks in domesticated birds are of concern for several reasons. There is potential for low pathogenic avian influenza viruses (LPAI) to evolve into strains which are high pathogenic to poultry (HPAI), and subsequent potential for significant illness and death among poultry during outbreaks. Because of this, international regulations state that any detection of H5 or H7 subtypes (regardless of their pathogenicity) must be notified to the appropriate authority.^[75][23] It is also possible that avian influenza viruses could be transmitted to humans and other animals which have been exposed to infected birds, causing infection with unpredictable but sometimes fatal consequences.

When an HPAI infection is detected in poultry, it is normal to cull infected animals and those nearby in an effort to rapidly contain, control and eradicate the disease. This is done together with movement restrictions, improved hygiene and biosecurity, and enhanced surveillance.^[74]

Humans – Avian flu viruses, both HPAI and LPAI, can infect humans who are in close, unprotected contact with infected poultry. Incidents of cross-species transmission are rare, with symptoms ranging in severity from no symptoms or mild illness, to severe disease that resulted in death.^[76][23] As of February 2024, there have been very few instances of human-to-human transmission, and each outbreak has been limited to a few people.^[77] All subtypes of avian Influenza A have potential to cross the species barrier, with H5N1 and H7N9 considered the biggest threats.^[25][26]

In order to avoid infection, the general public are advised to avoid contact with sick birds or potentially contaminated material such as carcasses or feces. People working with birds, such as conservationists or poultry workers, are advised to wear appropriate personal protection equipment.^[78]

Cattle – The H5N1 avian flu variant had first been identified in cattle around March 25, 2024. Since then the variant has been identified in 845 individual cases across 16 states as of early December, 2024.^[79] Recent tests have shown that the most common clade of the H5N1 variant found in cattle has been Eurasian lineage goose/Guangdong clade 2.3.4.4b which is also commonly found in commercial poultry and wild birds. According to the American Veterinary Medical Association, common clinical signs of H5N1 infection in dairy cattle include symptoms such as a reduced appetite, lower milk production, and abnormal milk appearance (e.g., thickened or discolored). While lactating cows are the most affected, illness is still often only reported in less than 10% of a herd, with a low mortality or culling rate of 2% or less. The United States Department of Agriculture (USDA) has started to require testing of lactating dairy cattle before interstate movement or travel and now mandates reporting of positive test results to the Animal and Plant Health Inspection Service (APHIS).^[80] Internationally, Canada tightened import rules for U.S. dairy cattle as a response.^[81] The USDA then introduced various forms of financial support for producers to bolster biosecurity and offset losses from production disruptions as a result of the spread. As for the future, the American Association of Bovine Practitioners (AABP) and the AVMA are coordinating with federal and state officials to provide further biosecurity guidance.^[82]

The commercial milk supply has not been affected, as milk from H5N1-affected animals is almost always diverted or destroyed before entering the food supply, and then as milk goes through pasteurization the virus becomes effectively inactivated. Testing of retail dairy products, including milk, butter, cheese, and ice cream, has found no live, infectious H5N1 virus which further supports the FDA's position that pasteurized milk is safe for consumption. The USDA's Food Safety and Inspection Service (FSIS) has also tested ground beef and muscle samples from culled dairy cows, with the results also confirming the absence of H5N1 in meat products. Any meat from condemned cows is prohibited from entering the human food supply. Beginning in September 2024, the FSIS has expanded testing of dairy cows that are going to be slaughtered to further safeguard the meat supply. For states permitting raw milk sales, the FDA has advised halting such sales if the milk may contain viable H5N1 virus. In December, a California dairy recalled raw milk and cream after multiple samples tested positive for the virus, which underscored the risks of consuming unpasteurized dairy products.^[83] The FDA recommended heat-treating milk intended for calf feeding to eliminate harmful pathogens. Consumers were also advised by the FDA to avoid raw milk, properly handle raw meat, and cook meat to an internal temperature of at least 165 °F, including meat used for pet food.^[84][82]

Other animals – a wide range of other animals have been affected by avian flu, generally due to eating birds which had been infected.^[85] There have been instances where transmission of the disease between mammals, including seals and cattle, may have occurred.^[86][87]

• A highly pathogenic strain of H5N1 caused flu outbreaks in 1959 in Scotland in chickens.^[88]
• In 1997, in Hong Kong, 18 humans were infected and 6 died in the first known case of H5N1 infecting humans.^[89] Subsequently 1.3 million chickens were culled in the territory of Hong Kong. The government also suspended the import of chickens from mainland China.^[90]

• In 2003 the first cases in humans since 1997 were diagnosed. Three people in one family were infected after visiting Fujian province in mainland China and 2 died.^[91][92]
• By midyear of 2003 outbreaks of poultry disease caused by H5N1 occurred in Asia, but were not recognized as such. In December animals in a Thai zoo died after eating infected chicken carcasses. Later that month H5N1 infection was detected in 3 flocks in the Republic of Korea.^[93]

• In January 2004 a major new outbreak of H5N1 surfaced in Vietnam and Thailand's poultry industry, and within weeks spread to ten countries and regions in Asia, including Indonesia, South Korea, Japan and China.^{[citation needed]}
• Variants have been found in a number of domestic cats, leopards, and tigers in Thailand, with high lethality.^[94] "The Thailand Zoo tiger outbreak killed more than 140 tigers, causing health officials to make the decision to cull all the sick tigers in an effort to stop the zoo from becoming a reservoir for H5N1 influenza.^[95]

• In January 2005 an outbreak of avian influenza affected thirty three out of sixty four cities and provinces in Vietnam, leading to the forced killing of nearly 1.2 million poultry.^{[citation needed]}
• In April 2005 there begins an unprecedented die-off of over 6,000 migratory birds at Qinghai Lake in central China over three months. Later in the year H5N1 was detected in Kazakhstan, Mongolia and Russia, Turkey, Romania, Croatia and Kuwait.^{[citation needed]}
• H5N1 was found to be infecting pigs in Indonesia, but without causing symptoms.^[96]

• In January 2006, the Turkish town of Do?ubayaz?t, was the centre of a H5N1 outbreak. Four children died from the disease after playing with chicken carcasses. 75,000 chickens in Do?ubayaz?t and in surrounding villages were killed as a precaution.^[97]
• In the first two months of 2006 H5N1 spread to India, north Africa, and Europe in wild bird populations.^{[citation needed]}
• February/March 2006 – A dead cat infected with the H5N1 bird flu virus was found in Germany.^[98]

• Significant outbreaks recorded in Japan, Hungary, Russia, United Kingdom, Pakistan, Turkey, Afghanistan, Myanmar, Bangladesh, Saudi Arabia, Ghana, Malaysia, Germany, Czech Republic, Togo, France and India.^{[citation needed]}

Many more outbreaks are recorded, in almost every country in the world, affecting both wild birds and poultry, with occasional spillover events infecting humans.^[13][60][61]

This section is an excerpt from 2020–2025 H5N1 outbreak.[edit]

Influenza A subtype H5N1

Influenza A virus subtype H5N1 Genetic structure Infection Human mortality Global spread in 2004 in 2005 in 2006 in 2007 2020–2025 Social impact Pandemic Vaccine

v t e

Since 2020, outbreaks of avian influenza subtype H5N1 have been occurring, with cases reported from every continent except Australia as of February 2025.^{[99][100][101][102]} Some species of wild aquatic birds act as natural asymptomatic carriers of a large variety of influenza A viruses, which can infect poultry, other bird species, mammals (including humans) if they come into close contact with infected feces or contaminated material, or by eating infected birds.^[103] In late 2023, H5N1 was discovered in the Antarctic for the first time, raising fears of imminent spread throughout the region, potentially leading to a "catastrophic breeding failure" among animals that had not previously been exposed to avian influenza viruses.^[104] The main virus involved in the global outbreak is as H5N1 clade 2.3.4.4b, genetic diversification of which with other clades (such as 2.3.2.1c) has seen an evolution in the ability to cause significant outbreaks in a broader range of species, mammals included.^{[105][106][107]}

H5N6 and H5N8 viruses with the H5-2.3.4.4b hemagglutinin (HA) gene became prominent globally in 2018–2020.^[106][108] In 2020, reassortment (genetic "swapping") between these H5-2.3.4.4b viruses and other strains of avian influenza led to the emergence of a H5N1 strain with a H5-2.3.4.4b gene.^[106] The virus then spread across Europe, first detected there in the autumn of 2020, before spreading to Africa and Asia.^[99] It continues to swap genes with local flu viruses as it crosses the globe.^{[109]: (fig.1)}

In March 2025, India reported eight outbreaks of H5N1 avian influenza in farms and backyard poultry in the southeastern state of Andhra Pradesh. The outbreaks resulted in the death or culling of 602,000 poultry, according to the World Organisation for Animal Health.^[110]

In October 2022 an outbreak of H5N1 on a Spanish mink farm showed evidence of being the first recorded case of mammal-to-mammal transmission, with 4 percent of the farm's mink population dying from H5N1-related haemorrhagic pneumonia. This coincided with H5N1 detections in the area among gulls and other seabirds, which are the presumed source of the outbreak.^[111][112]

A mass Caspian seal die-off in December 2022, with 700 infected seals found dead along the Caspian Sea coastline of Russia's Dagestan republic, worried researchers regarding the possibility that wild mammal-to-mammal spread had begun.^[113] A similar mass die-off of 95% of southern elephant seal pups in 2023 also raised concerns of mammal-to-mammal spread, as nursing pups would have had less exposure to birds.^[114] Between January and October 2023, at least 24,000 South American sea lions died from H5N1 flu, with the outbreak starting on the Pacific coast of Peru, moving down the coast to Chile and then up the Atlantic coast of Argentina.^[115]

In April 2024, spread of H5N1 amongst dairy cow herds in nine states of the USA strongly indicated the presence of cow-to-cow transmission possibly occurring while the animals were being milked.^[116][117] Although mortality in bovines infected with H5N1 is rare, viable virus can be shed in the milk.^[116] Around 50% of cats that lived on the affected dairy farms and were fed unpasteurised milk from symptomatic cows died within a few days from severe systemic influenza infection, raising significant concerns of cross-species mammal-to-mammal transmission.^[118]

In March 2025 a sheep was found in Yorkshire, UK, infected with H5N1; it was culled. Extensive testing suggests that it was the sole non-avian victim locally, with, for example, its own lambs testing negative.^[119]

Novel, contagious strains of H5N1 were created by Ron Fouchier of the Erasmus Medical Center in Rotterdam, the Netherlands, who first presented his work to the public at an influenza conference in Malta in September 2011. Three mutations were introduced into the H5N1 virus genome, and the virus was then passed from the noses of infected ferrets to the noses of uninfected ones, which was repeated 10 times.^[120] After these 10 passages the H5N1 virus had acquired the ability of transmission between ferrets via aerosols or respiratory droplets.

After Fouchier offered an article describing this work to the leading academic journal Science, the US National Science Advisory Board for Biosecurity (NSABB) recommended against publication of the full details of the study, and the one submitted to Nature by Yoshihiro Kawaoka of the University of Wisconsin describing related work. However, after additional consultations at the World Health Organization and by the NSABB, the NSABB reversed its position and recommended publication of revised versions of the two papers.^[121] However, then the Dutch government declared that this type of manuscripts required Fouchier to apply for an export permit in the light of EU directive 428/2009 on dual use goods.^[i] After much controversy surrounding the publishing of his research, Fouchier complied (under formal protest) with Dutch government demands to obtain a special permit^[122] for submitting his manuscript, and his research appeared in a special issue of the journal Science devoted to H5N1.^{[123][124][125]} The papers by Fouchier and Kawaoka conclude that it is entirely possible that a natural chain of mutations could lead to an H5N1 virus acquiring the capability of airborne transmission between mammals, and that a H5N1 influenza pandemic would not be impossible.^[126]

In May 2013, it was reported that scientists at the Harbin Veterinary Research Institute in Harbin, China, had created H5N1 strains which passed between guinea pigs.^[127]

In response to Fouchier and Kawaoka's work, a number of scientists expressed concerns with the risks of creating novel potential pandemic pathogens, culminating in the formation of the Cambridge Working Group, a consensus statement calling for an assessment of the risks and benefits of such research.^[128][129]

• Antigenic shift
• Avian influenza virus
• Favipiravir
• Fujian flu
• H5N1 clinical trials
• H7N9
• Influenzavirus A
• International Conference on Emerging Infectious Diseases
• National Influenza Centers
• Swine influenza
• Zoonosis

Wikimedia Commons has media related to H5N1.

Wikinews has news related to:

Avian Flu

• Influenza Research Database – Database of influenza genomic sequences and related information.
• WHO World Health Organization
  • WHO's Avian Flu Facts Sheet for 2006
  • Epidemic and Pandemic Alert and Response Guide to WHO's H5N1 pages
  • Avian Influenza Resources (updated) – tracks human cases and deaths
  • National Influenza Pandemic Plans
  • WHO Collaborating Centres and Reference Laboratories Centers, names, locations, and phone numbers
• FAO Avian Influenza portal Archived 2025-08-14 at the Wayback Machine Information resources, animations, videos, photos
  • FAO Food and Agriculture Organisation – Bi-weekly Avian Influenza Maps – tracks animal cases and deaths
  • FAO Bird Flu disease card
  • FAO Socio-Economic impact of AI Projects, Information resources
• OIE World Organisation for Animal Health – tracks animal cases and deaths
  • Official outbreak reports by country Archived 2025-08-14 at the Wayback Machine
  • Official outbreak reports by week
  • Chart of outbreaks by country Archived 2025-08-14 at the Wayback Machine

European Union

• Health-EU Portal EU response to Avian Influenza.
• Avian influenza – Q & A's factsheet from European Centre for Disease Prevention and Control

United Kingdom

• Exotic Animal Disease Generic Contingency Plan – DEFRA generic contingency plan for controlling and eradicating an outbreak of an exotic animal disease. PDF hosted by BBC.
• UK Influenza Pandemic Contingency Plan by the National Health Service – a government entity. PDF hosted by BBC
• UK Department of Health. Archived 2025-08-14 at the Wayback Machine

United States

• Center for Infectious Disease Research and Policy. Archived 2025-08-14 at the Wayback Machine Avian Influenza (Bird Flu): Implications for Human Disease – An overview of Avian Influenza
• PandemicFlu.Gov U.S. Government's avian flu information site
• USAID U.S. Agency for International Development – Avian Influenza Response
• CDC, Centers for Disease Control and Prevention – responsible agency for avian influenza in humans in US – Facts About Avian Influenza (Bird Flu) and Avian Influenza A (H5N1) Virus
• USGS – NWHC National Wildlife Health Center – responsible agency for avian influenza in animals in US
• Wildlife Disease Information Node A part of the National Biological Information Infrastructure and partner of the NWHC, this agency collects and distributes news and information about wildlife diseases such as avian influenza and coordinates collaborative information sharing efforts
• HHS U.S. Department of Health & Human Services's Pandemic Influenza Plan