Major bird migration flyways - Credit CDC EID Journal#18,398
Twenty years ago, HPAI H5 was viewed as a regional problem; a poultry virus restricted to Southeast Asia which occasionally spilled over into humans. While it could be carried by waterfowl, most of its spread was chalked up to illicit poultry trade.
In 2005 a new clade of the virus (2.2) appeared at Qinghai Lake in Tibet, and for the first time managed to escape the confines of Asia (see EID Journal: H5N1 Branching Out), turning up six months later in mute swans in Croatia (cite).
Changes in the virus appeared to have improved its carriage via migratory waterfowl. By the end 2005, 17 (mostly Asian) countries had reported infections, but in 2006 the virus would appear in an additional 39 countries.
By the end of 2007, the virus was endemic in the Middle East, well established in West Africa, and was a frequent return visitor to Europe. Fortunately, carriage by wild birds was still spotty, and strict culling of infected poultry prevented the virus from getting a solid foothold in Europe.
But repeatedly over the years new clades would emerge - and a new subtype (H5N8) - which incrementally improved the virus's ability to spread via migratory birds. In early 2014, a clade 2.3.4.4 H5N8 virus abruptly appeared in South Korea, ripping through their poultry industry.
By the end of that year, this new and improved clade had done what no other H5 had done before; it had crossed from Siberia to Alaska, bringing the first HPAI H5 epizootic to North America.
While devastating, this epizootic was short-lived, and by summer all traces of the virus had disappeared (see PNAS: The Enigma Of Disappearing HPAI H5 In North American Migratory Waterfowl).
The virus was still not able to maintain itself long-term in wild and migratory birds.
The following year, another reassortment occurred in Russia (see EID Journal: Reassorted HPAI H5N8 Clade 2.3.4.4. - Germany 2016), which led to the unprecedented 2016-2017 epizootic in Europe, one which saw numerous subtypes (H5N8, H5N5, H5N2, H5N9, etc.) emerge, and an increased host range among avian species.
Additional reassortments, several new subclades (e.g. 2.3.4.4b), and the emergence of competing subtypes (H5N6 then H5N1) would appear over the next 3 years, with the virus gaining new abilities to infect - and persist - in a growing number of bird species.
In 2017, the virus pushed south through Central Africa, reaching the Southern Hemisphere for the first time.
In 2020, H5N1 would re-emerge, and in 2021 the virus would make another great leap - crossing the North Atlantic and
arriving first in Eastern Canada - then spreading rapidly across North America,
arriving in South America the following fall.
The H5 virus continues to expand its avian host range (see DEFRA: The Unprecedented `Order Shift' In Wild Bird H5N1 Positives In Europe & The UK), as well as branching out into many more mammalian species (e.g. cattle, sheep, goats, rodents, cats, etc.).
Today, the H5 has made it to every continent except Australia, and many scientists fear that conquest is only a matter of time (see Australia : Biodiversity Council Webinar on HPAI H5 Avian Flu Threat).
Like a snowball rolling down a mountainside, H5N1 is gaining both mass and momentum. Where that leads is unknowable, but the H5 virus we face today is not your father's avian influenza.
All of which brings us to an excellent research article, published in GeoHealth, which looks at this decades-long evolution of the HPAI H5 virus, and how its spread by wild and migratory birds has changed over the years.
The full open-access report is very much worth reading in its entirety. You'll find the link, some excepts, and a link to a press release below.
A Geospatial Perspective Toward the Role of Wild Bird Migrations and Global Poultry Trade in the Spread of Highly Pathogenic Avian Influenza H5N1
Mehak Jindal, Haley Stone, Samsung Lim, C. Raina MacIntyre
First published: 25 March 2025
https://doi.org/10.1029/2024GH001296
Abstract
This study presents the interplay between wild bird migrations and global poultry trade in the unprecedented spread of highly pathogenic avian influenza, particularly the H5N1 clade 2.3.4.4b strain, across the world and diverse ecosystems from 2020 to 2023. We theorized the role of migratory birds in spreading pathogens as various wild bird species traverse major flyways between the northern and southern hemispheres.
Simultaneously, we analyzed the global poultry trade data to assess its role in H5N1's anthropogenic spread, highlighting how human economic activities intersect with natural avian behaviors in disease dynamics. Lastly, we conducted spatial hotspot analysis to identify areas of significant clustering of H5N1 outbreak points over different bird families from 2003 to 2023.
This approach provides a strong framework for identifying specific regions at higher risk for H5N1 outbreaks and upon which to further evaluate these patterns with targeted intervention studies and research into what is driving these patterns. Our findings indicate that both the poultry sector and wild bird migrations significantly contribute to global H5N1 transmission, which helps better understanding of H5N1 transmission mechanisms when combined with ecological, epidemiological, and socio-economic perspectives. The results are intended to inform policy-making and strategic planning in wildlife conservation and the poultry trade to improve public health and animal welfare globally.
Key Points
- We investigated the role of wild bird migration in the inter-continental spread of avian influenza on a global scale
- We analyzed the global poultry trade data to highlight how human economic activities intersect with disease dynamics
- Our findings indicate that both the poultry sector and wild bird migrations significantly contribute to avian influenza transmission
Plain Language Summary
The unprecedented scale and simultaneous infection of avian influenza across multiple species raise concerns about the potential threats to human health, especially in the upcoming years, if not months. The looming increase in bird migrations to the south adds a layer of complexity and urgency to the situation. As we navigate this evolving landscape, it becomes imperative to closely monitor and comprehend the altered dynamics of the virus to implement effective strategies for mitigating the risks associated with human infections.
In this study, we tracked the movement of some wild birds according to their seasonal migration along with the incidence of avian influenza. While the spread patterns revealed that the avian influenza had started in Asian countries, it is not clear how it spread from Asia to Europe because, with the birds we analyzed, it was unable to find a flyway from Asia to Europe.
However, every spread after the first incidence of avian influenza in Europe can be correlated with the seasonal migration of birds from one country to the other. Europe to Greenland to North America to South America can be established with different wild birds along with the spread from Europe to Africa.
(SNIP)
Analysis from 2005 to 2023 indicated a cyclic occurrence of the H5N1 every 5 years. However, a noteworthy deviation from this established pattern has become apparent in the latest outbreak since 2020. The ecological dynamics of the virus seem to have undergone a significant shift, manifesting in an unprecedented surge in cases compared to previous outbreaks. What distinguishes this event is the simultaneous and extensive infection of poultry, birds, and mammals during the same season—a phenomenon not witnessed in prior instances.
(Continue . . . )
New carrier birds brought avian flu to Europe and the Americas
Unexpected wild bird species, from pelicans to peregrine falcons, are transporting the virus from poultry to new places around the world and changing where the risk of outbreaks is highest
25 March 2025
(Excerpt)Far more bird species than ducks, geese and swans are transporting highly pathogenic H5N1 today, the study found. Cormorants, pelicans, buzzards, vultures, hawks, and peregrine falcons play significant roles in spreading avian flu. That makes them both victims and vectors of the disease and upends traditional approaches to monitoring H5N1 spread and predicting and responding to outbreaks. Culling of poultry birds worked in the past to mitigate burgeoning outbreaks, but it has failed to stop the current outbreak.
“We’ve got to think beyond ducks, geese and swans,” MacIntyre said. “They’re still important, but we have to start looking closely at these other species and other routes and think about what new risks that brings.”
Monitoring wild birds at a global scale is very difficult, so managing poultry bird populations is all the more important, she said. “We can do more about factors in our control — agriculture and farming.” Free-range birds, for instance, are more likely to contact wild birds, so managing them requires more vigilance. And pigs are “an ideal genetic mixing vessel” for viruses, so keeping pigs and poultry in close proximity is dangerous, she said.
“It’s a global problem, and it requires global solutions,” MacIntyre said.
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