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Rapid risk assessment on incursion of
HPAI H5N8 into housed or not housed
poultry flocks and captive birds
29 January 2021
Situation as at 26 January 2021
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© Crown copyright 2021
You may re-use this information (excluding logos) free of charge in any format or medium, under the
terms of the Open Government Licence v.3. To view this licence visit
www.nationalarchives.gov.uk/doc/open-government-licence/version/3/ or email
PSI@nationalarchives.gsi.gov.uk
This publication is available at www.gov.uk/government/publications
Any enquiries regarding this publication should be sent to: IADM@apha.gov.uk
www.gov.uk/defra
http://www.nationalarchives.gov.uk/doc/open-government-licence/version/3/mailto:PSI@nationalarchives.gsi.gov.ukhttp://www.gov.uk/government/publicationsmailto:IADM@apha.gov.ukhttp://www.gov.uk/defra
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Contents
Summary ............................................................................................................................................. 4
Introduction ........................................................................................................................................ 6
Hazard Identification ......................................................................................................................... 10
Previous outbreaks of HPAI H5N8: ................................................................................................... 12
Current Situation ............................................................................................................................... 12
Risk Question .................................................................................................................................... 16
Risk Levels ..................................................................................................................................... 16
Entry Assessment .......................................................................................................................... 16
Exposure Assessment........................................................................................................................ 22
Domestic poultry ........................................................................................................................... 24
Captive birds ................................................................................................................................. 25
Ratites ........................................................................................................................................... 25
Game birds .................................................................................................................................... 26
Consequence assessment ................................................................................................................. 26
Conclusions ....................................................................................................................................... 28
Assumptions and Uncertainties ........................................................................................................ 30
References ........................................................................................................................................ 30
Annex 1 ............................................................................................................................................. 32
Annex 2 ............................................................................................................................................. 42
Annex 3 ............................................................................................................................................. 43
Annex 4 ............................................................................................................................................. 46
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Summary
This is an update of a rapid risk assessment undertaken on 26 November 2020 in
response to findings of HPAI H5N8 in poultry (on 02 November 2020) and wild birds
(09 November 2020). Since then, there have been further findings of HPAI H5N8 in
poultry, captive birds and wild birds in the UK, HPAI H5N1 in one backyard flock as
well as HPAI H5N1, H5N2 and H5N5 in wild birds. All updates made on 26 January
2021 are shown in red for ease of reference.
1. In October 2020 the risk of AI H5N8 incursion through migratory wild waterfowl
was increased to MEDIUM on the basis of outbreaks in north-west Europe.
2. The report of HPAI H5N8 in a broiler-breeder rearing unit flock in Cheshire (AIV
2020/02) on Monday 2 November was the first confirmed event of HPAI H5N8 in GB
since 2017. Two wild geese tested positive for HPAI H5N8 in south-west England on
3 November 2020. The risk of AI H5N8 incursion through movements of migratory
wild waterfowl was increased to HIGH on 6 November 2020 and then to VERY HIGH
in early December.
3. To 26 January, HPAI H5N8 has been detected at 12 poultry premises in
England with three outbreaks in captive birds; 1 poultry premises in Scotland; 2
poultry premises in Northern Ireland, with one outbreak of HPAI H5N1 confirmed in
poultry in England. To 26 January 2021 the last infected premises detected in GB
was in Devon, SW England, on 29 December 2020, while that in Northern Ireland in
County Antrim was detected on 11 January 2021. Wales reported an outbreak of
HPAI H5N8 on 27 January 2021 at a game rearing establishment.
4. There have been numerous reports of HPAI H5N8 in a range of wild bird
species, including migratory birds, resident birds and bridging species (including
gulls and a few corvids, namely Eurasian magpies) in Europe and UK. The arrival of
wild waterfowl to overwinter in the UK has by and large ended, and numbers are
expected to have peaked in December and January, depending on the species and
also the weather conditions in Continental Europe. Large populations of migratory
water fowl are still present in the UK. These birds will remain here till March/April and
will start departing in numbers from early/mid-March.
5. As of 26 January 2021 there were 299 wild bird positive findings of H5 in
England, Wales, and Scotland across 41 counties, and 25 different species. Of
there, 274 tested were subtyped as H5N8, 10 H5N1, 6 H5N5 and 9 H5Nx. The total
number of positive wild birds detected in addition to the detection of multiple H5
HPAI subtypes in the same epidemic event is unparalleled in the UK.
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6. As a result of the ongoing infection pressure, the risk of AI H5N8 incursion in
wild birds is maintained at VERY HIGH.
7. There has been a pattern of spread consistent with previous disease epidemics
in which wild bird transmission was a primary factor. There is substantive evidence
that spread of H5 HPAI to GB by migrating wild waterfowl has happened on
numerous occasions since 2006.
8. Given the large poultry population and the proportion which are outdoor and in
regions close to large aggregations of wild waterfowl, we consider the risk of
exposure of poultry across the whole GB sill to be MEDIUM (where stringent
biosecurity is applied) and still to be HIGH (where biosecurity is sub-optimal). An
Avian Influenza Prevention Zone (AIPZ) is in place, and personnel should be taking
additional biosecurity measures.
9. Housing free range poultry could reduce the likelihood of infection incursion, by
reducing both the direct/indirect contact of free range poultry with wild waterfowl and
contact with the contamination in the environment. An EFSA analysis of the
2016/2017 HPAI H5N8 epidemic concluded that housing birds gave a two-fold
reduction in risk of virus incursion into poultry houses. However, other measures
were equally or more effective (preventing wild bird contact and improving
biosecurity measures and education).
10. However, to be effective, housing must be accompanied by thorough
biosecurity measures to prevent the disease from being introduced to the poultry
through contaminated fomites (e.g. human behaviours affecting spread) or by other
items that are taken into or enter the housing. Under some circumstances, it will not
be possible to house poultry, captive birds and breeding game birds, whether for
practical or welfare reasons relating to their husbandry needs, and so housing will
not be universally achieved.
11. An AIPZ was declared in England, Wales and Scotland with additional housing
measures that came into force from 14 December 2020. This means all bird keepers
in GB (whether they have pet birds, commercial flocks or just a few birds in a
backyard flock) are required by law to take a range of biosecurity precautions,
including housing their birds (except in very specific circumstances). Any legal
requirements to house and take biosecurity measures should be kept under review
and adapted as needed to reflect emerging evidence, including levels of compliance
with housing and biosecurity measures and the disease picture across Europe.
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Introduction
Across Northern Europe and Russia, and the Middle East since September 2020,
HPAI H5N8 infection has been detected in multiple species of wild bird, sometimes
prior to the detection of the same virus in various types of domestic poultry. The OIE
Reference Laboratory at Weybridge has confirmed this strain is different to the HPAI
H5N8 virus circulating in East Europe earlier this year and different to the virus
circulating in 2016/2017.
Outbreaks and cases (wild birds) reported in the lead up to the first reports of HPAI
H5N8 in the UK on 09 November 2020 are shown in Table 1. In early November a
rapid risk assessment was undertaken to address the risk of incursion of H5N8 HPAI
into housed and non-housed birds (domestic poultry and captive birds) from contact
with migratory wild waterfowl from Europe during the 2020/2021 winter season. This
was reviewed on 26 November 2020.
Since then, there have been further findings of HPAI H5N8 in poultry, captive birds
and wild birds in the UK, HPAI H5N1 in one backyard flock as well as HPAI H5N1,
H5N2 and H5N5 in wild birds.
Table 1: Outbreaks and cases of HPAI H5N8 in Central Asia, Middle East and
Europe to early November 2020.
Date Country Details
August Central Russia, Kazakhstan Multiple poultry farms and wild bird
cases
September Russia (Caspian Sea);
Kazakhstan, Israel
Multiple poultry farms and wild bird
cases
10/10/2020 Russia (West near Belarus) Poultry – 28,000
16/10/2020 EU (Netherlands) Eurasian wigeon (live)
Two migration pathways contribute to infected wild waterfowl flying out of central
Russia/Kazakhstan. The first is the Black Sea Mediterranean pathway which
contributed to reported cases in the Middle East (Israel) as birds fly to Africa in
October. European countries along this route would include those in Central and
South-eastern Europe. The second is the East Atlantic route which contributed to
cases in the North European countries, particularly Scandinavia, Germany,
Denmark, Poland, Ireland and GB. There are not clear boundaries between these
migration routes and the birds will have mixed between them to some degree on the
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breeding grounds. Multiple waterfowl species may be found at the same breeding
ground sites and at the same wintering sites. The numbers of HPAI H5Nx cases in
wild birds and captive birds reported in Europe in the week commencing 19 January
2021 are presented in Table 2.
Table 2: Current outbreaks of HPAI H5Nx in domestic poultry and captive birds
and cases in wild birds (from 19 to 26 January 2021), according to official
reporting sources. Note that this is a rapidly changing picture and new disease
reports are being made as we draft this risk assessment. (Annex 3 lists the wild bird
species involved in these reports).
Country
H5 H5N3 H5N5 H5N8
Total Wild/Captive
Birds
Wild/Captive
Birds Poultry
Wild/Captive
Birds Poultry
Wild/Captive
Birds
Belgium 1 1
Czech
Republic 1 1
Denmark 1 15 16
Finland 1 1
France 102 1 103
Germany 2 5 3 3 13
Ireland 1 3 4
Italy 1 1
Norway 3 3
Poland 2 1 3
Romania 2 2
Spain 1 1
Sweden 1 2 3
Ukraine 1 1
Total 3 3 1 6 108 32 153
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An Avian Influenza Prevention Zone (AIPZ) has been declared in England, Scotland
and Wales (effective from 5pm on the 11 November 2020) with additional housing
measures in force from 14 December 2020. This means all bird keepers (whether
they have pet birds, commercial flocks or just a few birds in a backyard flock) are
required by law to take a range of biosecurity precautions, including housing their
birds (except in very specific circumstances). Elsewhere, a housing order has been
put in place in the Netherlands, southern Norway and in the north German state of
Schleswig-Holstein. In the epizootic of 2016/2017, many EU MSs put in place a
housing order. The orders may cover just certain sectors of commercial poultry and
certain high risk areas.
The effectiveness of a housing order is difficult to assess. In 2016/2017 it is possible
there would have been a higher number of outbreaks without an order in place;
however, in France, Germany and Hungary, countries with the highest number of
outbreaks and with housing orders in place, there was secondary spread, indicating
poor biosecurity in some sectors, rather than primary contact with wild birds per se.
The EU has recently warned that secondary spread between establishments keeping
anseriforme species is observed (PAFF, 2020, and communication from Cion).
EFSA carried out a comprehensive review of the outbreaks of HPAI H5N8 in
2016/17 to assess the risk of introduction into poultry from migratory and residential
wild birds (EFSA, 2017). The opinion concluded that once virus is introduced to a
wild bird population, a critical population size is required before virus amplification
and further wild bird-associated geographical spread of the virus can take place.
Therefore, there is an increased likelihood of incursion into poultry farms most
closely located to large gatherings of wild birds (including but not exclusively
waterfowl) of target species1 during the migration season. Once the migratory birds
leave (from March onwards usually) the risk of incursion usually reduces but in cases
in which non-migratory birds are still testing positive, there will be a continual, albeit
lower, risk.
The opinion also concluded that the relative risk reduction for entry is three fold by
preventing access to water bodies, that housing gives a further two fold reduction,
and by applying routine biosecurity there is a further four fold reduction in risk while
high biosecurity is a 44 fold reduction in risk.
The opinion recommends that the following biosecurity measures for housed birds
which should be applied are: separating from wild birds; separate waterfowl from
gallinaceous poultry; provide potable drinking water; implement a hygiene lock for
1 The list of target species is available in Annex II Part 2 of Commission Decision 2010/367/EU on the implementation by Member States of surveillance programmes for avian influenza in poultry and wild birds.
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each poultry house and provide biosecurity training to all personnel. For non-housed
birds, it was recommended to restrict access to birds for people and provide
biosecurity training to personnel as the most feasible and sustainable measures. At
all times, feed must be provided indoors only, wild bird access should be restricted;
and contacts with other poultry premises limited. Feed and water could be provided
under a roof or a horizontal fabric for non-housed birds. The opinion used expert
knowledge elicitation to gather evidence on the biosecurity measures and a lack of
biosecurity awareness in the staff on sites was commonly reported.
A further supporting document to EFSA opinions on the risk of introduction of HPAI
into poultry farms in general (EFSA, 2017a) was a systematic review of previous
outbreaks to identify risk factors and concluded that the main risk factor for
introduction is contact with wild birds or fomites contaminated with wild bird faeces.
Other important risk factors were poultry species (waterfowl and turkeys are higher
risk); production system, where outdoor systems are higher risk than indoor; and
presence of biosecurity flaws.
This rapid risk assessment is aimed at providing advice around the most appropriate
form of prevention zone order for the different sectors and establishing whether there
is evidence to help make decisions around mandatory housing. Any prevention order
would only be put in place in an area not already under restriction for a notifiable
avian disease.
Under article 6(1) of the Avian Influenza and Influenza of Avian Origin in Mammals
(England) (No 2) Order 2006 (“the Order”), the Avian Influenza and Influenza of
Avian Origin in Mammals (Scotland) Order 2006 and the Avian Influenza and
Influenza of Avian Origin in Mammals (Wales) (No 2) Order 2006, the Secretary of
State must carry out a risk assessment in order the declare an Avian Influenza
Prevention Zone.
Measures to reduce the risk of transmission of avian influenza
6.—(1) If, after carrying out a risk assessment, the Secretary of State considers such action necessary to reduce the risk of transmission of avian influenza to poultry or other captive birds from wild birds or from any other source, he must—
(a) declare an avian influenza prevention zone in all or part of England/Scotland/Wales; or
(b) serve or require an inspector to serve a notice on the occupier of any premises where poultry, other captive birds or any categories of poultry or captive birds specified in the notice are kept.
(2) A declaration or notice under paragraph (1) must impose such measures as the Secretary of
State considers necessary to reduce the risk of transmission of avian influenza.
(3) When deciding the measures to impose under paragraph (2), the Secretary of State must consider whether measures are necessary—
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(i) to prevent direct or indirect contact which wild birds might otherwise have with poultry and other captive birds;
(ii) to reduce the risk of feed and water provided to poultry and other captive birds being contaminated with avian influenza virus; and
(iii) to reduce the risk of the spread of avian influenza between premises.
(4) The power of the Secretary of State to impose measures by declaration or notice under this article includes the power—
(a) to require poultry and other captive birds to be housed or otherwise kept separate from
wild birds;
(b) to require poultry or other captive birds or categories of such birds specified in the
declaration or notice to be housed or otherwise kept separate from other poultry and captive
birds;
(c) to require that poultry and other captive birds are provided with feed and water to which
wild birds have no access;
(d) to require keepers of poultry and other captive birds and others who come into contact
with such birds to cleanse and disinfect their footwear and take such other biosecurity
measures as a veterinary inspector or an inspector under the direction of a veterinary
inspector may require;
(e) to ban or limit the collection of poultry or other captive birds at any fair, market, show,
exhibition, race or other gathering;
(f) to ban or limit the use of birds of the orders Anseriformes (including ducks, geese and
swans) and Charadriiformes (including gulls, murres, terns, avocets, puffins, woodcock,
oystercatchers, sandpipers, plovers, surfbirds, snipes and skimmers) as decoys during bird
hunting.
Hazard Identification
The hazard identified is the avian influenza virus, predominantly H5N8 HPAI subtype
but other virus subtypes have been detected including H5N1, H5N2, H5N3 and
H5N5.
Virus has been isolated from outbreaks and wild birds in the EU during the current
epizootic, and the World Animal Health Organisation (OIE) and Food and Agriculture
Organisation (FAO) International Reference Laboratory (IRL) for Avian Influenza (AI)
at the Animal and Plant Health Agency (APHA) has undertaken sequence analysis.
Diagnostic evaluation utilised frontline molecular assays and whole genome
sequencing techniques to define the genetic composition of the causative agent.
Importantly, despite various virus subtypes and genotypes, the haemagglutinin gene
is highly conserved (amongst these strains to date in the 2020/21 epidemic) and this
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factor critically underpins fundamental virus properties such as infectivity and
transmissibility.
The virus from the GB outbreaks maps across the whole genome with the H5N8
viruses (reported by the lab as part of an international collaboration) found elsewhere
in Europe (multiple countries), Middle East and Central Asia (including Russian
Federation and Kazakhstan) during the last 6 months (and therefore distinct from the
strain that caused widespread outbreaks in the EU in the first part of this year).
Topology of the phylogenetic tree for the HA gene indicates that all UK report case
isolates detected during Autumn/Winter 2020/2021 (including 17 H5N8 and 1 H5N1)
cluster within clade 2.3.4.4b alongside all European isolates for which sequence is
available. These viruses also cluster with H5N8, H5N5 and H5N1 HPAI viruses from
the across the EU, and Russia, again within clade 2.3.4.4b. Interestingly, the H5N1
viruses cluster together whilst the H5N5 and H5N8 viruses appear to be more
closely related with H5N5 viruses sitting at different points within the main
Autumn/Winter 2020 cluster. All Autumn/Winter 2020 detected viruses cluster
together within clade 2.3.4.4B, but separately from the H5N8 viruses responsible for
the outbreaks in Europe in late 2019- early 2020. Specifically, the HA gene appears
to descend from the HPAI H5N8 viruses which caused the previous epidemic wave
that caused outbreaks across the Eurasian and African continent in 2016-2017, and
is highly related to the H5N8 viruses which have been circulating in Egypt since 2017
with the closest genetic linkage being an isolate detected in Iraq in May 2020.
On the other hand, the three H5N1 viruses are almost identical and result from
multiple reassortment events with LPAI viruses circulating in wild birds in Eurasia,
from which they have acquired six (PB2, PB1, PA, NP, NA and NS) out of eight (6/8)
gene segments. Whether this reassortment event has occurred in Europe or Asia is
an issue that cannot be assessed from the data available to date.
Wild bird cases in England, Wales, and Scotland have tested positive for HPAI
H5N1, H5N2, H5N5, and H5N8. The detection of four H5 HPAI subtypes in the same
epidemic event is unparalleled in the UK or indeed at European level. All these
viruses are genetically closely related through their haemagglutinin gene, which is
the key viral gene influencing pathogenesis, host range, transmission, and host
immunity. Continued virus change by genetic reassortment in wild birds is not
unexpected, and further genetic variation at genome level may be expected as the
epidemic progresses.
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Previous outbreaks of HPAI H5N8:
In 2014/2015 several outbreaks of H5N8 HPAI were detected in poultry in Europe
(Germany, Italy, Netherlands and GB) all in housed birds and were attributed to
indirect contact with infected wild waterfowl. In the Netherlands, there were four
separate incursions and two were linked premises. In Germany, there were just two
separate introductions and, in both Italy and GB (England), only single premises
were affected. No direct links were found between the different countries. Wild
waterfowl testing positive for H5N8 HPAI were only detected in Netherlands and
Germany, in Eurasian wigeon and teal, after the outbreaks had been notified. No
significant wild bird mortality was observed in 2014/2015.
In the HPAI H5N8 2016/2017 epizootic, virus spread rapidly in migratory and non-
migratory wild waterfowl in Europe causing mortalities in these birds. This was
strikingly different to previous years and indicated a change in the virus pathogenicity
for certain species of bird. By the end of the season most EU countries, as well as
Europe, the Middle East and parts of southern and west Africa had reported cases of
this virus.
Current Situation
This year to date, there is a lack of evidence for whether some species of wild
waterfowl do not show clinical signs on infection with this virus strain and whether
the virus can continue to circulate in non-migratory, sedentary birds. However,
considering the number of birds found dead in non-breeding sites across Europe (in
the hundreds) compared to the total number of birds in these sites (likely to be in the
many thousands), it is feasible that the virus is circulating widely with low mortality
(see Map 1).
This pattern of geographical distribution follows that seen for the epizootic of H5N1
HPAI in 2005/2008 in Europe, and in H5N8 HPAI in 2016/2017 in Europe. In those
years, spread occurred along a similar route of migratory wild waterfowl causing wild
bird die-offs in North and Central Europe (see maps 2 and 3).
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Map 1: Current outbreaks and wild bird cases of H5N8 HPAI (as of 26 January
2021).
Map 2: Outbreaks and wild bird cases of HPAI H5N8 in Europe in 2016-2017
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Map 3: Outbreaks and wild bird cases of H5N1 HPAI in Europe, North Africa
and the Middle East in 2005-2008
Therefore, this new epizootic is following a similar pattern of transmission in wild
birds and spill-over into domestic poultry as observed with HPAI H5N8 in 2016-2017,
and H5N1 HPAI in 2005 – 2008 and it can be expected that the current H5N8 HPAI
epizootic will continue to cause issues with the poultry sector for several months to
come, if not for many months, if the virus continues to circulate in migratory and then
in non-migratory waterfowl in Europe.
There are three emerging trends apparent in Continental Europe. The first trend of
note is that the rate of new wild bird case reports has fallen, and the total number of
wild bird cases has levelled off in December although may be slightly increasing
again in the last month. Thus, each European country only reported a handful of wild
birds cases in the week beginning 19 January 2021 (Table 2). To 26 January 2021,
this year there have been 93 wild bird cases of 844 in total since October; of which
38 were reported to OIE on 22 January. At this stage in the 2016/17 epizootic there
had been 625 wild bird cases, with cases rising to over 1,000 by mid-February 2017
in the second peak. There is, however, a suggestion of a second rise in wild bird
cases in early January this year; but it is too early to tell if this is a true second peak,
as was observed at the end of January 2017 in the 2016/17 H5N8 epizootic. ADNS
(data to 17/1/21) for EU MSs, plotted weekly by the EU Ref laboratory (IZSVe,
2021), show wild bird cases dropping off to very low numbers at the end of 2020
compared to the peak of ~150 per week in November 2020.
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However, the second week of January saw this jump to ~35 wild bird cases per week
falling to ~18 in the third week. Care needs to be taken in interpretation of wild bird
data in relation to the risk to poultry because surveillance activity may have reduced
in some countries over Christmas period. Wild bird cases and submissions appear to
be reducing in the UK, with associated lower infection pressure, but there will be a
lag effect with virus in the environment as the virus decays after wild bird
amplification. Although we have seen a definite reduction in the rate of new cases in
the UK, this cannot be solely attributed to the decrease in wild bird cases in
Continental Europe. The reduction in new cases in wild birds in the UK will ultimately
translate into lowering the infection pressure in the environment. The trends in wild
birds in both Europe and the UK are in a positive direction given normal infection
dynamics in wild birds.
The second trend in Europe is that overall the number of outbreaks reported in
poultry after appearing to increase slightly, particularly in Germany and Poland, is
now reducing. The exception is France, which has reported a large increase in
numbers as H5N8 spreads though the duck industry in the south-west (Table 2). The
situation in south-west France should not be used as an indicator for the UK
because it is not due to primary cases from wild birds, but due to secondary spread
in a challenging sector.
The third development is that outbreaks are now being reported in south-east
Europe, with Hungary, Slovakia and Romania now reporting HPAI. Until recently, this
epizootic has mainly been an outbreak of north-western Europe, although Italy and
Slovenia have been affected. This represents diffusion of the virus over a wider area
as local populations of wild birds become infected through localised movements.
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Risk Question
What is the risk of incursion of H5N8 HPAI into housed and non-housed birds (domestic
poultry and captive birds) from contact with migratory wild waterfowl from Europe during the
2020/2021 winter season?
Risk Levels
For the purpose of this risk assessment, the following EFSA-derived definitions will
be used:
Negligible So rare that it does not merit to be considered
Very low Very rare but cannot be excluded
Low Rare but does occur
Medium Occurs regularly
High Occurs very often
Very high Events occur almost certainly
Entry Assessment
The wild waterfowl population in GB is relatively well understood. Several NGOs
conduct regular surveys for the wild waterfowl at known wintering and breeding sites
across GB. In particular, the British Trust for Ornithology (BTO), The Joint Nature
Conservation Councils (JNCC), the Royal Society for the Protection of Birds (RSPB)
and the Wildfowl and Wetlands Trust (WWT) carry out counts of wild birds. Their
evidence shows the sites of the largest waterbird aggregations in GB (see Figure 1).
The Wash is one of the premier sites for wintering waterbirds in GB with over
300,000 birds counted each year, while other top ten sites include the Somerset
levels, the Dee estuary, the Humber estuary and the Ribble, Alt and Mersey
estuaries, but there is a variation of at least 10% from one year to the next, attributed
to the winter weather conditions. There are 53 sites with at least 20,000 birds
wintering year after year across GB.
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Figure 1. Wild bird assemblage abundance in GB, derived from 109 species
considered most relevant for the transmission of AI to poultry flocks. (From Hill
et al. (2019) Scientific Reports 9:19973)
In terms of migration, the wild waterfowl will have been arriving in GB from Northern
Europe since August / September and numbers generally peak in December to
January. While some species, such as swans, will be site loyal from one year to the
next, others will be less so, and there will be mixing between species in the large
aggregation sites. Outward migration will start again in March to May.
Expert opinion from the JNCC and BTO suggests that Eurasian wigeon, a species of
migratory duck, are most abundant in Netherlands and GB with some testing positive
for HPAI H5N8 in Germany, the Netherlands and the UK. Wigeon start arriving in the
UK from September with numbers building through October to December.
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Furthermore cases of live trapped or positive shot wild birds in Netherlands and Italy
suggests that “healthy” wild birds are carrying infection.
Figure 2. The combination of wild bird assemblages and poultry density as a
risk map, which informs the poultry survey, targeting the high risk areas.
See Annex 2 for estimated numbers of wild birds entering GB in comparison to the
Netherlands and Italy in any year (Flutest project 2014). It can be seen from these
data that for most migratory species, fewer birds arrive here than to the Netherlands
in any one year; nevertheless, there are still significant numbers. Although these
data are some years old, at present, we are seeing a usual seasonal flow of
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migratory birds, and this is not currently affected by any cold weather conditions in
Europe.
The frequency of peak occurrence of waterbird species by month and by county are
available on the Wetland Bird Survey website http://app.bto.org/webs-reporting/. For
example, the monthly frequency of the common teal and the Eurasian wigeon (the
two highest risk species according to Flutest) are shown here, based on the 2018/19
survey:
http://app.bto.org/webs-reporting/
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Given the daily reports of HPAI H5N8 in wild birds in Belgium, Denmark, Germany,
Ireland, Italy and Netherlands that were seen in October/November, the increasing
numbers of wild birds being found dead in Europe and the total populations involved,
and, more recently, the cases in Sweden, Norway, Romania, Hungary, Slovakia and
Slovenia, it is likely that there are still birds which are not showing clinical signs and
are able to migrate to the UK, although at this stage in late January this is less likely.
There is evidence that sedentary birds present in GB have been infected may still be
infectious with ongoing transmission and a source of virus circulation in other birds
within GB.
There is a system for wild bird surveillance in GB, whereby found dead birds from
target species are reported either by wardens at reserves and wetland sites, or by
the public for testing at the NRL. As of 26 January 2021, there were 299 wild bird
positive findings of H5 in England, Wales, and Scotland across 41 counties, and 25
different species. 274 tested were subtyped as H5N8, 10 H5N1, 6 H5N5 and 9
H5Nx. The total number of positive wild birds detected, in addition to the detection of
multiple H5 HPAI subtypes in the same epidemic event, is unparalleled in the UK.
HPAI H5N8 virus has been identified in a range of wild bird species, with mute
swans, greylag geese and Canada geese representing the majority of detections.
This is in contrast to 2016, when initial detections were found primarily in tufted
ducks, swans and gulls.
The Barnacle geese over-wintering in the Netherlands are different populations from
the GB populations, and probably come through the Baltic from Norway/western
Siberia, while the Barnacle geese that winter in Scotland either come from
Greenland (via Iceland) or from Svalbard (via north Norway). There, avian influenza
is rarely detected and represent a different migration flyway. In autumn, Greylag
geese mainly move south from Scandinavia, or in southern GB are resident bird
populations. Eurasian wigeon are migratory ducks from breeding areas in northern
Russia and Eastern Europe.
Although there is considerable uncertainty around the transmission of HPAI H5N8
from migratory to local sedentary species, HPAI H5N8-positive findings in GB are in
both migratory birds and resident birds (mallards, Canada geese, mute swans)
suggesting that significant local transmission of virus is occurring. These are detailed
in Annex 4.
A qualitative estimate of the numbers of migrating higher risk species of waterbirds
arriving in GB from various areas of Europe, Asia and Africa in autumn/winter is
shown in Table 3 by species (Gale et al. 2014).
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21
However, the key message is that these birds have now arrived in the UK in these
numbers and we are now detecting both further spread within these populations
wintering within the UK and also increasingly spill-over event to our indigenous
sedentary populations as shown in Annex 4. Thus, the dynamic is shifting which
correlates to more sporadic wild bird cases which overall reduces infection pressure
in the environment and therefore reducing risk to poultry. In summary, the
indigenous birds provide an ongoing background risk after multiple primary
introductions via migratory waterfowl.
Table 3. Qualitative estimation of number of higher risk species of waterbirds
migrating from different regions of the world to GB, the Netherlands and Italy
(per year) (n). This is based on numbers of birds in Annex 2. Negligible numbers
are excluded (Gale et al. 2014)
Species Western
Europe
Eastern
Europe
Asia West
Africa
East and
Southern
Africa
Bewick’s swan L L VL
Whooper swan L VL VL
Mute swan M VL
Greater white-fronted goose VL VL VL
Greylag goose VL
Red-breasted goose VL
Eurasian wigeon H M M L
Common teal H L L L
Mallard M L L VL
Northern pintail M L L L VL
Garganey VL VL VL VL VL
Northern shoveler L VL L VL
Common pochard L L L VL
Tufted duck M L L
Black-headed gull H L L
Number of individual birds in each qualitative category: >1,000,000 Very high (VH); 100,001 -
1,000,000 High (H); 10,001 – 100,000 Medium (M); 1,001 – 10,000 Low (L); 1 - 1,000 Very Low
(VL); 0 Negligible (excluded)
Based on the numbers of wild bird cases in north-western Europe to date this
season compared to the 2016/17 outbreak, it is concluded that the wild bird infection
pressure is higher and there is evidence that sedentary wild bird species in the UK
are now infected (see Annex 4).
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22
Bridging species include several sedentary indigenous birds, such as gulls and
corvids. Many gulls but also a few corvids (namely Eurasian magpies), have tested
positive for HPAI H5N8 on the Continent and in the UK. As bridging species, gulls
are known to have long daily flight patterns between feeding sites, such as open
farmland or rubbish tips, and their night roosts such as reservoirs and gravel pits.
They are likely to have a role in fomite transmission from areas where there is
environmental contamination. Fomite transmission via multiple pathways is
particularly important in the current situation, considering the environment is high risk
across the country.
We therefore consider the likelihood of there being infected wild waterfowl present in
GB is VERY HIGH as a country-wide assessment. However, there will be regional
variation, based on the proximity to aggregation sites for non-breeding wild
waterfowl. LOW uncertainty.
Exposure Assessment
There are multiple pathways for the exposure of poultry to notifiable avian diseases
(Defra, 2018).
These include:
• Contact with infected poultry such as live birds, hatching eggs and day old
chicks of poultry
• Contact with live infected wild birds, particularly waterfowl
• Contact with poultry products and by-products of infected poultry,
• Contact with contaminated feed, water, bedding, equipment, vermin or
clothing / footwear of people in contact with infected birds or contaminated
environment.
Biosecurity advice which poultry keepers should practise at all times of the year are
focussed on these pathways as there is a constant low risk of incursion from any
notifiable avian disease being introduced into poultry because LPAI viruses circulate
constantly in wild waterfowl. The EFSA report from 2017 used a combination of
systematic review of all poultry outbreaks and expert knowledge elicitation from
members of the poultry sectors. What was clearly stated in the expert knowledge
elicitation was the need to not only implement biosecurity measures which are
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23
feasible and sustainable but also the importance of training poultry workers in what
these measures mean.
Contact with live infected wild birds, particularly waterfowl:
Wild birds will forage for food away from their assemblages and geese in particular
may move up to 7km on a daily basis. As more migratory birds arrive and if the
weather worsens over winter, they may also move away from the coast and be
observed inland. In addition, gulls which can act as a bridging species, fly tens of km
a day to feed, returning in the evening to their over-night sites.
Housing birds will reduce direct contact with wild waterfowl. It will not prevent any of
the other pathways through which disease may enter a poultry premises. Other
biosecurity measures will be more important. The likelihood of contact with wild
waterfowl will be dependent on the number of such species in the near environment
and how attractive the site is to such birds. The presence within the poultry premises
of a pond or open feed bins are two well-known factors which make direct contact
with wild waterfowl more likely for poultry with access to the outside environment.
Expert opinion is that the virus will retain infectivity in the environment at low
temperatures, at least to 55 days at 4oC (Ian Brown, APHA, Pers. Comm.). This
means the environment could remain contaminated for several weeks or more.
Preliminary APHA data indicate that the current H5N8 HPAI virus could have
extended survival properties, compared to the 2016 H5N8 virus, but further work is
ongoing.
As the most likely contact of poultry kept outdoors with wild waterfowl will be in those
areas where there are high concentrations of these species, the likelihood of direct
contact with wild waterfowl or indirect contact with their faeces would be greater for
those poultry establishments in close proximity to, or with sites attractive to, wild
waterfowl. Therefore, where there are no large aggregations of wild waterfowl, the
risk is lower for this particular pathway, but there are still other pathways which could
lead to the introduction of any notifiable avian disease. It is worth reiterating that H7
LPAI viruses which circulate in wild waterfowl, when introduced into housed layer
hens, have been known to mutate into HPAI which is a more disruptive infection to
control, due to the increased size in control zones.
Although in the 2016/2017 season, the (few) outbreaks in commercial poultry
establishments in GB were all housed birds, since not all poultry premises
throughout GB were tested, it is not possible to say whether outdoor flocks were
exposed and did not exhibit clinical signs.
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24
Incursion through imported live animals or products:
For the other pathways, contact with other live birds (i.e. trade in poultry, hatching
eggs, day old chicks) will be dependent on the business itself and the commercial
activities. Contact with products or by-products from infected birds will be dependent
on the activities of people entering the premises and bringing such products with
them and it should be noted that swill feeding is not legal. These will not be
addressed in detail for this assessment. However, housing birds will not impact on
this risk.
Contact with contaminated feed, water, bedding, equipment, vermin or clothing /
footwear of people in contact with infected birds or contaminated environment:
Contamination of feed, bedding and water by wild birds can be prevented by
sourcing such products from safe sources and keeping such items in containers
which no wild birds can access. The site can be made less attractive to wild
waterfowl by preventing access to any ponds on site or excluding ponds and pools of
standing water from the range and making sure feeding areas are protected.
Contact with contaminated equipment, footwear and clothing can be prevented by
making sure all personnel in contact with the birds use disinfectants appropriately.
This will be particularly important where birds are housed, as contact with the birds is
more frequent, as feed, bedding and water must be brought into the houses and
birds must be checked for welfare issues or eggs collected from inside the houses.
Visitors to the farm should also be recorded for security and to help tracing
exercises. Other biosecurity practices should be employed to ensure wild birds are
separated from flocks such as feeding birds indoors or under cover, discouraging
wild birds from landing, removing wild bird contamination and draining watercourses,
removing feeders and water stations from the range, ensuring good building
maintenance and regular inspections for signs of wild bird/rodent access. Vermin
control is strongly recommended because rodents act as fomite spreaders.
Above all, the EFSA opinion recommended ensuring all personnel are trained in, and
practise, good biosecurity, regardless of whether birds are housed or not.
Domestic poultry
The GB poultry sector is complex and seasonally variable. There is a requirement for
all poultry keepers in England, Scotland and Wales with more than 50 birds to be
registered with the British Poultry Register. For fewer than 50 birds it is voluntary.
Therefore, any data available will not necessarily include the backyard or smallholder
community. In comparison to data available in 2013, the outdoor chicken sector has
decreased from 62% of total holdings to 30% in 2018.
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25
The poultry sector can be designated in the following way with the various
populations according to the 2018 poultry register:
Poultry Type Number of
Birds
As proportion
of total
population
Number of
holdings
As proportion of
total poultry
holdings
Total Chickens 270986618 85.45% 10125 51.98%
Outdoor
Chickens 33500062 10.56% 5879 30.18%
Layers 47186064 14.88% 5454 28.00%
Broilers 166134899 52.39% 1663 8.54%
Total Turkeys 8462070 2.67% 1069 5.49%
Outdoor
turkeys 1642191 0.52% 443 2.27%
Total ducks 4108083 1.30% 1364 7.00%
Outdoor ducks 981325 0.31% 878 4.51%
Total geese 146332 0.05% 187 0.96%
Outdoor geese 116826 0.04% 125 0.64%
Total CDGT 283703103 89.46% 12745 65.43%
Total Pheasant 23918729 7.54% 4733 24.30%
Total Partridge 9512172 3.00% 2001 10.27%
Total Poultry 317134004 19479
Note: the “outdoor” label is only an estimate and the NCP Salmonella survey
estimates the free range population to be 55% of the layer birds and 18% of turkeys.
Captive birds
Captive birds, such as those held in collections, zoos or approved bodies are already
semi-housed and should be kept separate from wild waterfowl. For some, this will be
difficult to prevent access to their water environment (penguins, pelicans, flamingos
etc), but it is unlikely it will be possible to house indoors, so every effort should be
made to prevent wild waterfowl access. There were outbreaks in captive birds in
Europe (in zoos) in 2016/2017 and a derogation exists in EU legislation which means
birds may not have to be destroyed, unless they are in contact with the infected
collection.
Ratites
Ratites, such as ostriches, cannot be housed on a long term basis. Outbreaks of
closely related H5N8 HPAIV have been reported in commercial ostriches in South
Africa since 2017. Ratites are therefore susceptible to some strains of HPAIV at least
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26
and there has been a case in Germany of an emu showing clinical signs in a zoo and
therefore these birds should also be considered susceptible.
Game birds
The majority of game birds have already been released for the shooting season and
therefore are considered wild birds and outside the scope of a prevention order
around housing. Some will still be kept in pens and could not be housed due to
welfare issues, therefore the pens themselves would need to be netted where
possible to ensure the birds cannot escape and forage locally. Game bird keepers
should use the guidance
https://www.gfa.org.uk/user_files/uploads/Bird_Flu_and_Gamebirds.pdf
Captive birds used as decoys would be at risk of increased contact with wild
waterfowl. If they remain at one place for the duration of the fowling season, then
they will not come into contact with domestic poultry; however, if the birds are moved
around to other sites or spend any time at a premises where domestic poultry are
kept, this is an increased risk for the poultry. It is illegal to release by hand captive
birds for the purpose of being shot immediately after their liberation, under Part 1,
Section 8 of the Wildlife and Countryside Act, 1981.
Given the large poultry population and the proportion which are outdoor and in the
regions close to the large aggregations of wild waterfowl, we consider the risk of
exposure of poultry across the whole GB still to be MEDIUM (where stringent
biosecurity is applied) to HIGH (where there are biosecurity breaches) (LOW
uncertainty). Twenty infected premises have been identified across England,
Scotland, Northern Ireland and, most recently, an infected premises with game birds
in Wales. Furthermore, HPAI H5N8 (and other subtype combinations) has been
confirmed in many wild birds in England, Scotland, Wales and Northern Ireland.
However, it is important to emphasise both the role of wild ducks and geese visiting
poultry premises, and the bridging species flying over or visiting sites. An AIPZ is in
place, and personnel should be taking additional biosecurity measures. The
pathways which lead to disease incursion are not prevented by housing per se, but
housing birds is a risk reduction measure.
Consequence assessment
Any outbreak of notifiable avian disease has a significant impact on GB poultry
industry, through the trade and economic impacts on the producer and the sector.
This is the same for any notifiable avian influenza virus. Average costs to
government may be between £2 and £4 million per outbreak, depending on the
https://www.gfa.org.uk/user_files/uploads/Bird_Flu_and_Gamebirds.pdf
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27
number of birds involved and time taken to complete secondary C&D and return to
disease free status.
Housing birds which are not used to housing can cause welfare issues. Making sure
their environment is enriched (e.g. with toys), that they have plenty of room to move,
access to feed and water, clean bedding and the ability to display natural behaviours
are all welfare priorities. For ducks, their bedding must be changed regularly as they
will mess it quickly and they need access to water so they can clean their feathers. If
the birds become stressed, they may be more prone to infections or other
behaviours which impact on welfare. Certain species cannot be housed for welfare
reasons or because they are already considered wild: geese, ratites and gamebirds.
GB is required to deliver surveillance for H5 and H7 LPAI incursions in poultry
(including H5 and H7 HPAI in Anseriformes) under Council Directive 2005/94/EC
and Commission Decision 2010/367/EU. An option for Risk Based Surveillance is
available and has been applied in GB since 2012. The output of the model used for
the risk based targeting of surveillance in poultry identified 2231 10km grid squares
where wild waterfowl and registered poultry flocks are co-located as identified from
2016 “Sam” (APHA’s registration database) and British Trust for Ornithology data.
For these grid squares, a risk score >0 could be assigned and then ranked into 6
bands of equal numbers of grid squares (approximately 373 in each rank) – where
Rank 1 represents the lowest and rank 6 the highest risk. The remaining areas of GB
where no poultry premises were registered have been assigned a “zero risk” score
even though non-commercial poultry may be resident and wild waterfowl abundant.
The actual risk of AI incursion therefore will not be “zero” in these areas.
The area of any prevention order which included housing could be done under a
Ministerial Order, at a national, regional or county level or at a smaller area level. In
terms of delineating these areas, the interactive map available at
https://defra.maps.arcgis.com/apps/webappviewer/index.html?id=8cb1883eda5547c
6b91b5d5e6aeba90d uses the risk-based poultry survey model, which already takes
into account the areas of high wild waterfowl populations (Figure 1) and a “foraging
distance” for waterfowl. Consideration should also be paid to the different poultry
populations which could be housed without compromising welfare. A national order
or even a regional order would be of significant consequence to the poultry sector
where the risk reduction is not considered to be significant. That consequence is
around the possible increase in risk of the other pathways which could bring avian
disease into contact with the poultry, through increasing the level of contact with
workers and increasing transmissibility of viruses between the birds when they are in
close contact with one another. This could also increase the risk of mutation of LPAI
viruses into HPAI viruses as seen with previous outbreaks in Europe for H7 viruses.
https://defra.maps.arcgis.com/apps/webappviewer/index.html?id=8cb1883eda5547c6b91b5d5e6aeba90dhttps://defra.maps.arcgis.com/apps/webappviewer/index.html?id=8cb1883eda5547c6b91b5d5e6aeba90d
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Options for the area of any prevention order are therefore considered as
follows:
Sector National Regional County level Small 10/10
km2 zones
Chickens Not
considered
appropriate
based on the
variable risk
level for any
species
Not
considered
appropriate
based on the
variable risk
level for any
species
Possible and easiest
to mandate but not all
premises at same risk
level
Preferred but
difficult to
operate
Turkeys
Ducks
Geese Not considered
appropriate for these
species
Not considered
appropriate for
these species
Gamebirds
Ratites
Captive birds Recommendation around separation of
birds and preventing wild waterfowl
access
Conclusions
Housing should only be applied in conjunction with other biosecurity measures, but it
should be noted that it will not be effective if used as a single measure. The trigger
for such an order should be associated with a primary case in wild waterfowl or high
confidence that a poultry outbreak is related to contact with wild birds. In the current
outbreak, there have been twelve outbreaks of HPAI H5N8 in poultry confirmed on
premises in England, and one outbreak confirmed on a premises in Scotland. There
have also been three cases of HPAI H5N8 in captive birds in England, and one case
of H5N1 in backyard chickens, in England. In addition, there have been two
outbreaks in poultry confirmed in Northern Ireland. On 27 January H5N8 was
confirmed at a game rearing establishment near Amlwch, Isle of Anglesey, Wales.
Housing should only be applicable to those species where the welfare of the birds is
not compromised.
In GB the sensitivity of our wild bird avian influenza surveillance has been increased
to ensure collection and analyses of any number of targeted species of wild birds
(essentially ducks, geese, swans, gulls and birds of prey) known to carry risk of
infection with AI viruses. Single dead birds of target species where possible will be
collected and tested.
At this stage at the end of January few migrating waterfowl are expected to enter the
UK from Europe even if the weather were to deteriorate significantly in the coming
weeks. Even if a few more birds did fly over, this would not necessarily increase the
estimated risk areas alluded to in this document, given the VERY HIGH level already
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29
assessed for wild birds. The migration season for wild waterfowl to overwinter in the
UK has by and large ended, and numbers are expected to have peaked in
December and January, depending on the species and the weather conditions in
Continental Europe. A large population of migratory water fowl are still present,
however, and will not be leaving the UK until March/April. Furthermore, there is
evidence of spread to sedentary birds in the UK.
If the HPAI H5N8 virus circulates in native sedentary wild waterfowl and becomes
established, as happened with HPAI H5N1 in 2005-2008, then housing could not be
applied for such a long period. In the current demographic, sedentary species are
now largely those testing positive. The survival of the virus in the environment during
winter means the risk will not decrease for a period of weeks at the earliest. The
higher survival rate of the virus in the environment during winter means the risk of
environmental transmission remains, and hence, the continued risk of secondary
spread into indigenous UK wild bird species and naïve non-indigenous. Higher
environmental temperatures, together with increasing sunlight intensities will reduce
environmental levels of H5N8 and the associated risks.
As discussed above, a second peak occurred at this time of year in the 2016/17
H5N8 epizootic. Monitoring weekly changes over the next few weeks is therefore
important with regard to trends (up or down) in infection risk based upon number of
poultry incursions and level of detections in wild birds both in the UK and on the
continent.
If the risk has not changed and no new outbreaks or cases have been detected in
GB, despite passive surveillance and testing of wild birds found dead, the prevention
order should be reviewed after the peak migratory wild waterfowl occurrence is past,
i.e. at end of January. However, an outbreak of HPAI H5N8 was confirmed in GB on
28 January 2021.
The following conditions could be used to inform when the risk levels will be reduced.
Firstly, the time of year and if our migrant non-breeding waterfowl have left GB;
secondly if time has lapsed since the last reported case and there is a significant
reduction in infection pressure from the Continent; thirdly if the temperature has
started to increase with higher sunlight levels, then the environmental contamination
and transmission would be reduced. These could form part of the “exit strategy”
although other factors including the uncertainties listed below need to be considered.
As the housing order has been applied, an exit strategy is now required and this
should also be based both on a risk assessment and other epidemic considerations.
However, an expectation of no wild bird cases could be disproportionate i.e. one
case per week when surveillance sensitivity has been maximised will not correlate
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30
with a very high wild bird risk. The housing order was introduced on the basis of
numerous wild bird cases and several poultry outbreaks and the same criteria in
reverse could be used as an exit strategy in addition to using the three scientific
conditions above to inform the risk assessment.
Assumptions and Uncertainties
• The wild bird counts for this year are not known and we are using an annual
assessment based on previous years.
• Other wild waterfowl species (although this assessment considers the most
abundant) may also be important for the transmission of this virus.
• The patterns of movement of gulls are more complex than waterfowl. They prefer to
roost around land tips and reservoirs, therefore these should not be ignored as
potential sites of concern for proximity to poultry farms.
• The evidence for the economic benefits and dis-benefits of housing birds is not part
of this assessment.
• The 2016/2017 epidemic allowed experts to analyse the likely risk factors leading to
an incursion of avian influenza and while housing birds was assessed as giving a
twofold reduction, other factors such as preventing access to wild birds (three fold)
and improving biosecurity (four fold) are also significant.
• While housing may prevent direct contact with wild waterfowl, it could increase
indirect contact with contaminated environment and the birds may be under stress,
leading to more disease transmission and greater likelihood of viral mutation. Regular
contact with wild birds and their LPAI viruses may produce an environmental
“vaccine” protection against HPAI viruses.
References
Defra (2018)
https://assets.publishing.service.gov.uk/government/uploads/system/uploads/attachment_da
ta/file/759784/ai-rationale-hras-nov2018.pdf
EFSA (2017) J.efsa.2017.4991
EFSA (2017a) So.efsa.2017.EN-1282
Gale, P. et al. (2014) entry of H5N1 highly pathogenic avian influenza virus into Europe
through migratory wild birds: A qualitative release assessment at the species level. Journal
of Applied Microbiology 116, 1405-1417.
https://assets.publishing.service.gov.uk/government/uploads/system/uploads/attachment_data/file/759784/ai-rationale-hras-nov2018.pdfhttps://assets.publishing.service.gov.uk/government/uploads/system/uploads/attachment_data/file/759784/ai-rationale-hras-nov2018.pdf
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31
PAFF (2020) https://ec.europa.eu/food/sites/food/files/animals/docs/reg-
com_ahw_20201020_pres_hpai_efsa.pdf
https://ec.europa.eu/food/sites/food/files/animals/docs/reg-com_ahw_20201020_pres_hpai_efsa.pdfhttps://ec.europa.eu/food/sites/food/files/animals/docs/reg-com_ahw_20201020_pres_hpai_efsa.pdf
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Annex 1
Data on migratory waterfowl in Scotland
Wintering sites in
Scotland
Origin HPAI priority
for Scotland
Bewick’s Swan Does not tend to winter
in Scotland. Previously
flew through Scotland
from Netherlands to
Ireland, but less so
now
Western Siberia Very low
Whooper Swan Caerlaverock, grazes
in fields so could
contact poultry
Iceland Very low*
Mute Swan Generally sedentary Very low
Greylag Goose Wintering flocks in
Scotland, but sites in
extreme north and
north-west of Scotland
are occupied by a
resident population.
Greylags feed
exclusively on
agricultural land and
could contact poultry
Non-resident UK
Greylags originate
from Iceland.
Wintering populations
in northern Germany,
Denmark,
Netherlands more
likely to fly to England
in cold weather
Very low
Barnacle Goose Winter in Caerlaverock
(Solway )and also west
coast and islands
South-west Solway
wintering populations
are from Spitzbergen,
while north-west are
from Greenland
Low
Pink-footed Goose Grazes in fields so
could contact poultry,
Loch of Strathbeg
(Aberdeenshire) is
wintering site for 20%
of world population.
Winters around east
coast, central belt and
Solway (Caerlaverock)
breeding grounds in
Spitsbergen, Iceland
and Greenland. UK
birds are from
Greenland, Iceland.
Very low
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33
Wintering sites in
Scotland
Origin HPAI priority
for Scotland
Bean Goose Rare in UK in general,
site in south-west
Scotland
Northern Eurasia,
Siberia, also eastern
population wintering
in south-east Asia
Very low
Greenland white-
fronted goose
(flavirostris)
West coast of Scotland Greenland Very low
Eurasian white-
fronted goose
(albifrons)
Rare in Scotland Northern Russia and
eastern population
wintering in South-
east Asia
Very low
Lesser white-fronted
Goose
Very rare vagrant Very low
Light-bellied brent
goose (hrota)
East Scotland, Solway,
central belt
Spitzbergen Very low
Light-bellied brent
goose (hrota)
West coast (and
Ireland)
Greenland Very low
Dark-bellied brent
Goose (bernicla)
Common in southern
England, but not in
Scotland
Northern Russia and
eastern population
wintering in South-
east Asia
Very low
Red-breasted Goose Very rare vagrant Very low
Eider Large wintering
population in Scotland,
all round coast, albeit
with 8 sites with counts
exceeding 1,500 birds.
Although, highly
gregarious, not likely to
come in contact with
poultry as sea duck
rarely found away from
coast due to
dependence on
mussels. Very rare
Low
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34
Wintering sites in
Scotland
Origin HPAI priority
for Scotland
inland, no need for
freshwater
Goosander Largely freshwater
catches salmon and
trout, unlikely to come
in contact with poultry
Goldeneye Diving duck, unlikely to
come in contact with
poultry
Birds from northern
Europe winter in
Scotland
Very low
Eurasian Wigeon Grazes on grass, so
opportunity to come in
contact with poultry.
Although an estuarine
bird, loss of eelgrass
has resulted in switch
to inland grass in
flooded marshy areas.
Largest wintering sites
in England not
Scotland
Some breed in
Scotland, many from
Eurasia
Medium
Common Teal Could come in contact
with poultry. England
has largest numbers
with Loch Leven
having smaller
numbers
Wintering population
drawn from complete
breeding range –
Iceland, northern
Europe, the Baltic
States, and a large
area of the Russian
Federation.
Medium
Northern Pintail
Mallard Main sites are in
England but widely
distributed. Could
come into contact with
poultry
Medium
Gadwall
Tufted Duck Diving duck, unlikely to
come in contact with
Large wintering
population in GB
Low
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35
Wintering sites in
Scotland
Origin HPAI priority
for Scotland
poultry. British
breeding birds
generally sedentary
during winter. Main site
in Scotland is Loch
Leven.
generally from
eastern parts of
European range
Pochard Diving duck, unlikely to
come in contact with
poultry. Low site fidelity
suggest highly mobile.
Loch Leven is principal
moulting site from end
of June
Wintering birds
originate mainly from
Baltic (62% from
Latvia) and Russia
Low
Greater Scaup Main sites are Solway
Firth, Loch Ryan,
Morray and the
Islands. Diving ducks
feed on mussels,
mainly coastal in
winter, unlikely to
contact poultry
Icelandic birds winter
in north-western
Scotland, those on
east coast from
Fennoscandian and
Russian populations
Low
References
Owen, M. (1980) Wild geese of the World. Batsford
Ogilvie, M.A. (1978) Wild geese. T&AD Poyser
Cramp, S. (1977) Handbook of the Birds of Eurpe the Middle East and North Africa.
The birds of the Western Palearctic. Volume 1, Ostrich to ducks.
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36
Data on migratory waterfowl in England/Wales
The focus is on those birds coming to England/Wales via the Baltic coast
Species Wintering sites in
England
Origin HPAI priority for
England/Wales
Bewick’s Swan Some 9,000 birds
winter in Britain
(mainly England
including south-east
England and central
England) and Ireland
Single population for
north-western Siberia
Medium –
because of small
numbers which
always fly
through the Baltic
Whooper Swan 16,000 birds in Britain
and Ireland, mainly
Scotland. Some sites
in eastern, northern
England such as
Welney WWT in
Norfolk.
Mainly from Iceland.
Very few of the
Russian and Fenno-
Scandinavian
breeding population
come as far as
England even in cold
weather, normally
winter in the Baltic
Very low –
because not from
Baltic
Mute Swan Generally sedentary
in Britain, Ireland and
importantly in the Low
Countries
Very low because
does not migrate
from Low
Countries, hence
Mute Swan cases
in NL are not a
concern
Graylag Goose Wintering flocks in
Scotland, but sites in
extreme north and
north-west of Scotland
are occupied by a
resident population.
Greylags feed
exclusively on
agricultural land and
could contact poultry
Non-resident UK
Greylags originate
from Iceland.
Wintering populations
in northern Germany,
Denmark,
Netherlands more
likely to fly to England
in cold weather
Very low
Barnacle Goose Mainly winter in
Scotland and northern
Ireland. Wild birds are
rare in England,
Wintering populations
are from Spitzbergen,
while north-west are
from Greenland. A
Very low
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37
Species Wintering sites in
England
Origin HPAI priority for
England/Wales
although there are
feral flocks
small number of
Russian birds which
winter in the
Netherlands could
come over to south-
east England in
severe weather.
Pink-footed Goose Grazes in fields so
could contact poultry.
Mainly East Anglia
and Lancashire.
UK birds are from
Greenland, Iceland
while Spitzbergen
breeding population
winters in Denmark,
West Germany and
the Low countries,
with a few reaching
Britain in severe
winters.
Low risk due to
small numbers
coming from
Denmark,
Germany in
severe winters,
presumably
south-east or
east coast of
England.
Bean Goose Rare in UK in general,
small numbers
wintering at sites in
East Anglia but not
many
Northern Eurasia,
Siberia, Finland
100,000 pairs breed
in western Siberia
Very low because
of low numbers in
England.
Greenland white-
fronted goose
(flavirostris)
Rare winter visitors to
England, a few winter
in Wales
Greenland Negligible
Eurasian white-
fronted goose
(albifrons)
Baltic-North Sea
group winters in the
Netherlands, Belgium,
England and Wales. In
England winters in the
selected sites in the
south (Severn
Estuary, Kent, East
Anglia)
Breeds in northern
Russia, Novoya
Zemlya and Kanin
Peninsula
Medium, comes
through the Baltic
to England each
year but not a
common bird.
Lesser white-fronted
Goose
Very rare vagrant, one
or two birds in
England each year,
most winter in the
Balkans
North Scandinavia,
western Siberia
Negligible
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38
Species Wintering sites in
England
Origin HPAI priority for
England/Wales
Light-bellied brent
goose (hrota)
Very small numbers in
England/Wales, more
in Ireland
Spitzbergen and
Greenland
Negligible
Dark-bellied brent
Goose (bernicla)
Common in coastal
sites and marshes in
southern England. Not
common inland or on
lakes.
Northern Russia and
eastern population
wintering in South-
east Asia
Medium risk of
H5N8 entry and
highly gregarious,
but unlikely to
contact poultry
because coastal.
Red-breasted
Goose
Very rare vagrant Very low
Shelduck Many resident in
England but some
migrate to moult in
tidal mud flats in north
Germany in July
Breeding population
returns back from
moult migration to
breeding range in
Britain
October/November
Medium risk of
entry of H5N8 but
generally
coastal/estuarine
bird.
Eider Winter around south
and east coast of
England although less
common than in
Scotland. Although,
highly gregarious, not
likely to come in
contact with poultry as
sea duck rarely found
away from coast due
to dependence on
mussels. Very rare
inland, no need for
freshwater
Relatively small
movements, rarely
over 200 km.
Very low
Goosander Largely freshwater
catches salmon and
trout, unlikely to come
in contact with poultry.
Winters in sites across
UK although
uncommon and many
Males summer moult
in north Scandinavia.
Breeders in Russia
and Fenno-
Scandinavia migrate
west to Baltic and
yeyond to
Very low
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39
Species Wintering sites in
England
Origin HPAI priority for
England/Wales
from breeding sites in
Scotland.
Netherlands and
Britain.
Goldeneye Diving duck, unlikely
to come in contact
with poultry with
wintering sites across
England.
Birds from northern
Europe, Russia winter
in the Baltic,
Denmark,
Netherlands and
Britain.
Low
Eurasian Wigeon Grazes on grass, so
opportunity to come in
contact with poultry.
Although an estuarine
bird, loss of eelgrass
has resulted in switch
to inland grass in
flooded marshy areas.
Bird is gregarious with
large wintering sites
across much of central
England.
Some 200,000 pairs
breed in western
Russia and 80,000
pairs in Finland.
Migrate through the
Baltic to winter in west
and south-west
Europe including
Germany,
Netherlands, France,
Britain and Ireland.
High
Common Teal Graze on grass and
could come in contact
with poultry. England
has large numbers
with wintering sites
across England. Bird
is gregarious.
Breeding birds from
north Russia,
Scandinavia, Baltic
States, north Poland,
north Germany and
Denmark fly south-
west in the autumn to
wintering grounds in
the Netherlands and
Britain. Winter
distribution between
Netherlands, England,
Wales and Ireland
greatly dependent on
weather; cold spells
cause immediate
westward movement.
High
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40
Species Wintering sites in
England
Origin HPAI priority for
England/Wales
Northern Pintail Scattered sites across
England.
Icelandic birds winter
in Britain (no risk) but
some from north-west
Russian, Finland and
Baltic States fly west
to winter in
Netherlands and
Britain, with
movement from the
Netherlands to Britain
in hard weather.
Low due to
smaller numbers
than other ducks
Mallard Many are resident in
UK. Many sites are in
England and widely
distributed. Could
come into contact with
poultry
Icelandic birds winter
in Britain (no risk) but
some from north-west
Russian, Finland,
Baltic States and
northern Germany fly
west to winter from
Denmark to north
France and in Britain.
Medium but
reduce to low
because bird is
not gregarious
Gadwall Many resident in
England and also
wintering sites mainly
in England.
Breeders in Germany,
Poland, and west
central Russia winter
in the Netherlands
and Britain.
Medium
Shoveler Many wintering sites
across England. Filter
feeder so restricted to
water unlikely to feed
in fields. Bird is
gregarious.
Breeders from Fenno-
Scandinavia and
Russia migrate west
and south-west to
Netherlands, Britain
and Ireland.
Medium because
although water-
feeder could
infect other
gregarious
waterfowl species
which feed in
fields.
Tufted Duck Diving duck, unlikely
to come in contact
with poultry although
highly gregarious.
British breeding birds
generally sedentary
during winter, and
Large wintering
population in GB
generally from
eastern parts of
European range,
Medium risk of
entry because
although diving
duck could infect
other gregarious
waterfowl species
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41
Species Wintering sites in
England
Origin HPAI priority for
England/Wales
many wintering sites
across England.
Russia and
Scandinavia.
which feed in
fields.
Pochard Resident population
but also many
wintering sites across
England and Wales.
Diving duck, unlikely
to come in contact
with poultry but highly
gregarious and may
infected other species.
Low site fidelity
suggest highly mobile.
Wintering birds
originate mainly from
Baltic (62% from
Latvia) and Russia
Medium risk of
entry because
although diving
duck could infect
other gregarious
waterfowl species
which feed in
fields..
Greater Scaup Mainly marine with a
few coming to inlake
lakes. Diving ducks
feed on mussels,
mainly coastal in
winter, unlikely to
contact poultry
Birds on east coast of
England from
Fennoscandian and
Russian populations
Low because
although highly
gregarious less
likely to contact
freshwater ducks.
References
Owen, M. (1980) Wild geese of the World. Batsford
Ogilvie, M.A. (1978) Wild geese. T&AD Poyser
Cramp, S. (1977) Handbook of the Birds of Eurpe the Middle East and North Africa.
The birds of the Western Palearctic. Volume 1, Ostrich to ducks.
-
42
Annex 2
Numbers of migratory birds (per year) entering GB, the Netherlands and Italy
calculated as the difference between totals of monthly counts (maximum -
minimum), taken from Flutest project work underpinning Gale et al. (2014).
HRS Bird Species GB, Wetland
Bird Survey
data of Austin
et al. 2008
The Netherlands (Hustings et al. 2008)
Italy, peak national
count in January
between 1990 and
2005. Atkinson et al.
(2006)
Bewick’s Swan Cygnus
columbianus
3,775 13,000 0
Whooper Swan Cygnus
cygnus
7,428 2,000 0
Mute Swan Cygnus olor 11,542 5,000 3,248
Greater White-fronted
Goose (European race)
Anser albifrons albifrons
1,341 600,000 11,049
Greylag Goose Anser
anser
72,980 150,000 5,392
Red-breasted Goose
Branta ruficollis
4 7 4
Eurasian Wigeon Anas
penelope
324,097 600,000 123,936
Common Teal Anas
crecca
126,498 50,000 97,529
Mallard Anas
platyrhynchos
97,872 180,000 208,000
Northern Pintail Anas
acuta
25,344 20,000 12,781
Garganey Anas
querquedula
38 (May) + 47
(Aug)*
80 (Apr) + 110
(Aug)*
223
Northern Shoveler Anas
clypeata
11,200 10,000 22,811
Common Pochard
Aythya ferina
24,160 45,000 42,189
Tufted Duck Aythya
fuligula
46,429 150,000 7,725
Black-headed Gull
Larus ridibundus
150,555 150,000 217,468
*Spring and autumn migration
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43
Annex 3
Species list for cases in wild birds (as of 7 am on 25/01/2021), according to
OIE.
Country Wild bird species affected
Belgium Canada Goose (Branta canadensis)
Common Wood Pigeon (Columba palumbus)
Egyptian Goose (Alopochen aegyptiaca)
Eurasian Curlew (Numenius arquata)
Eurasian Magpie (Pica pica)
European Herring Gull (Larus argentatus)
Great Crested Grebe (Podiceps cristatus)
Greater White-fronted Goose (Anser albifrons)
Greylag Goose (Anser anser)
Mute Swan (Cygnus olor)
Pink-footed Goose (Anser brachyrhynchus)
Czech Republic Mute Swan (Cygnus olor)
Denmark Barnacle Goose (Branta leucopsis)
Black-headed Gull (Chroicocephalus ridibundus)
Brant Goose (Branta bernicla)
Common Buzzard (Buteo buteo)
Common Eider (Somateria mollissima)
Common Pheasant (Phasianus colchicus)
Eurasian Curlew (Numenius arquata)
Eurasian Sparrowhawk (Accipiter nisus)
European Herring Gull (Larus argentatus)
Gadwall (Mareca strepera)
Greater White-fronted Goose (Anser albifrons)
Greylag Goose (Anser anser)
Mallard (Anas platyrhynchos)
Mute Swan (Cygnus olor)
Northern Gannet (Morus bassanus)
Northern Goshawk (Accipiter gentilis)
Peregrine Falcon (Falco peregrinus)
Pink-footed Goose (Anser brachyrhynchus)
Taiga Bean Goose (Anser fabalis)
White-tailed Eagle (Haliaeetus albicilla)
Whooper Swan (Cygnus cygnus)
Finland Common Pheasant (Phasianus colchicus)
France Black-headed Gull (Chroicocephalus ridibundus)
Brant Goose (Branta bernicla)
Common Buzzard (Buteo buteo)
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44
Country Wild bird species affected
Common Shelduck (Tadorna tadorna)
European Herring Gull (Larus argentatus)
Greylag Goose (Anser anser)
Mute Swan (Cygnus olor)
Red Knot (Calidris canutus)
Germany Accipitridae (unidentified) (Accipitridae (incognita))
Anatidae (unidentified) (Anatidae (incognita))
Anserinae (unidentified) (Anserinae (incognita))
Ardeidae (unidentified) (Ardeidae (incognita))
Charadriidae (unidentified) (Charadriidae (incognita))
Common Buzzard (Buteo buteo)
Crane (unidentified) (Grus (incognita))
Gull (unidentified) (Larus (incognita))
Haematopodidae (unidentified) (Haematopodidae (incognita))
Laniidae (unidentified) (Laniidae (incognita))
Passeridae (unidentified) (Passeridae (incognita))
Rallidae (unidentified) (Rallidae (incognita))
Strigidae (unidentified) (Strigidae (incognita))
Swan (unidentified) (Cygnus (incognita))
Hungary Great Egret (Ardea alba)
Ireland Barnacle Goose (Branta leucopsis)
Charadriidae (unidentified) (Charadriidae (incognita))
Eurasian Curlew (Numenius arquata)
Mute Swan (Cygnus olor)
Peregrine Falcon (Falco peregrinus)
Whooper Swan (Cygnus cygnus)
Italy Common Buzzard (Buteo buteo)
Eurasian Teal (Anas crecca)
Eurasian Wigeon (Mareca penelope)
Greater White-fronted Goose (Anser albifrons)
Greylag Goose (Anser anser)
Lithuania Mute Swan (Cygnus olor)
Netherlands Barnacle Goose (Branta leucopsis)
Charadriidae (unidentified) (Charadriidae (incognita))
Common Buzzard (Buteo buteo)
Eurasian Teal (Anas crecca)
Eurasian Wigeon (Mareca penelope)
Greater White-fronted Goose (Anser albifrons)
Greylag Goose (Anser anse
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