1. detection of IgM in CSF samples or in serum
2. haemagglutination inhibition tests
3. CF.

Control tools

Parameter 2 – Existence of control tools

Methods for preventing transmission:

Activities for control of these infections are individual prevention of mosquito bites by using protective clothing and repellents, control of vectors and vaccination of equines and some avian species. Surveillance using birds is also recommended.

Vaccination:

Regarding equine vaccination (in some cases EEEV vaccine is used in some birds), there is no effect of the vaccination in human health since equids are not good amplifiers for the virus.

EEE/WEE vaccines currently available are formalin-inactivated adjuvanted whole virus products and are distributed in different combinations as vaccines against EEEV and WEEV or adding also VEE and other agents for use in horses. These formalin-inactivated preparations were shown to be highly efficacious in protecting against clinical disease but the EEE vaccine preparation is made with a North American strain and it seems that they do not protect against South American strains (Dietz et al., ; Strizki and Repik, ). Other approaches to obtain second generation vaccines exists (Minke et al., ; Arechiga-Ceballos and Aguilar-Setien, ).

The availability of licensed vaccine products combined with an inability to completely eliminate risk of exposure justifies immunisation against EEE and WEE as core prophylaxis for all horses residing in or travelling to North America and any other geographic areas where EEE and/or WEE is endemic (Acha and Szyfres, ; AAEP, online).

The viruses are circulating only in the Western hemisphere. No presence in EU.

Outbreaks of EEEV can cause important loss in the equine industry as demonstrated by epidemics in 1938 in USA when the virus affected 185,000 horses or in Louisiana in 1947, where 14,334 horses were affected and the mortality rate was 83% (Hubalek et al., ). From 1956 to 1970, EEEV was identified in USA in 605 encephalitic horses out of 2620 analysed (Acha and Szyfres, ). WEEV, in a minor extension, can also cause disease in horses and 6000 equine cases were recorded in California (1930) with a mortality of 50%, and epidemics occurred in Canada in 1937 and 1938 with a mortality of 28% affecting 12,000 and 52,000 horses respectively (Hubalek et al., ). Also in the USA, 174,000 horses in 1937 and 184,000 in 1938 were affected by WEEV or EEEV and between 1956 and 1970, WEEV was isolated in 2015 encephalitic horses out of 2,620 analysed (Acha and Szyfres, ).

The economic impact for horses is not well established. As an example for other viruses such as West Nile Virus in USA, an epidemic caused 569 cases in horses with 22% mortality in North Dakota. Losses resulted in costs of US$ 1.5 million spent in medical services and due to inability to use horses for recreation purposes because of the disease (Ndiva Mongoh et al., ).

Humans get infected by the bite of an infected mosquito. No other route of transmission has been demonstrated. Infections could occur as sporadic cases, small outbreaks or epidemics if not controlled. Most human infections by EEEV are asymptomatic, but when CNS involvement occurs, it results in frequent and severe neurological signs, lesions, and sequelae. The mortality rate associated to human cases of EEE varies from 50% to 75% and the young are at greater risk of clinical disease. The early clinical illness involves a flu-like prodromal stage of about 5 days dominated by high fever and headache and death can occur within 3–5 days of infection (Calisher, ). Children commonly exhibit facial oedema. Paresis, paralysis, respiratory impairment, altered mental state and seizures are common neurological manifestations and many of these signs persist for long periods in patients who survive the acute illness. Survivors suffer from neurological sequelae, including convulsions, paralysis, and mental retardation.

WEEV causes asymptomatic or mild infections in humans, with non-specific symptoms such as sudden onset of fever, headache, nausea, vomiting, anorexia and malaise. Some patients may also present with altered mental status and weakness, with signs of meningeal irritation. The infection may cause encephalitis or encephalomyelitis, resulting in neck stiffness, confusion, visual disturbances, photophobia, tonic-clonic seizures, somnolence, coma, and death in rare cases. An estimated 90% of humans with WEE under the age of 1 year show severe CNS signs (Calisher, ). Estimates of the case fatality rate of WEE range from 3% to 15%. Fifteen to fifty per cent of the encephalitis survivors, especially young children, suffer from permanent neurological damage (mental retardation, emotional instability and spastic paresis). The mortality rate of a few cases of aerosolised WEE in humans, as those occurred in laboratory workers, was 40% (Hanson et al., ). WEEV has mortality range of 3–7%.

Neurological sequelae (confusion, visual disturbances, photophobia, seizures, somnolence, coma, intellectual disability, and emotional instability/behavioural changes and spastic paresis) in 15–30% of WEE survivors have been described. In the case of EEE survivors, convulsions, seizures, paralysis, intellectual disability and behavioural changes have been observed in 50–90% of the survivors (Ronca et al., ).

No data about disability-adjusted life year (DALY) are available. There is no specific treatment against these viruses and vaccines for humans are also recommended for laboratory workers or military personnel.

The impact on animal welfare is not well established although during EEE outbreaks, many avian species could develop illness with fever, ataxia, trembling, leg and generalised paralysis and death (Scott and Weaver, ; Acha and Szyfres, ; Hubalek et al., ; CFSPH, ). For infected horses, 80–90% develop acute and lethal disease, and about 66% of the survivors develop neurological sequelae (Scott and Weaver, ) while for WEEV mortality is about 20–30% (Acha and Szyfres, ; CFSPH, ).

Many wild rodents, amphibians, reptiles and other animals could be infected by these viruses but the viruses affect mainly equine and avian (mainly passerine birds) species. No data about the susceptibility of European species are available. The mortality in due to infection with EEEV or WEEV of wild animal species has not been calculated.

The non-controlled use of non-approved repellents for vector control could have some effect on the environment but strict regulations should be applied. To assess the potential impact on the environment of chemical biocidal products used to control potential outbreaks of vector-borne diseases, information was extracted from ECHA's website on approved active substances which may be used for controlling the relevant vector species (EFSA AHAW Panel, ). Any potential impact on the environment of the use of biocidal products beyond the intended uses, doses and target species as evaluated by European Chemicals Agency (ECHA) is unknown.

Persistence of EEEV or WEEV in the environment outside their hosts or vectors is not of concern.

EEEV and WEEV are included in the List of Human and Animal Pathogens and Toxins for Export Control by the Australia group (AG, online). They are classified in the category B [viral encephalitis alphaviruses (e.g. VEE, EEE, WEE)] of CDC Bioterrorism Agents (CDC, online-b). EEEV, except the South American genotype, is a select agent that requires registration with CDC and/or USDA for possession, use, storage and/or transfer since it has the potential to pose a severe threat to public health and safety, to animal and plant health, or to animal or plant products (CDC, online-a). Both viruses are listed in the OIE list of notifiable terrestrial and aquatic animal diseases (OIE, online).

On July 2011, only six countries (France, Germany, Italy, the Netherlands, Slovakia and Spain), belonging to the European Network for the Diagnostic of Imported Viral Diseases (ENIVD), had laboratories where specific detection of EEEV and/or WEEV could be carried out (ENIVD, online).

Methods available are in-house tests whose sensitivity and specificity need to be established.

There are no commercial, internationally recognised and/or OIE certified specific tools for diagnostic of these viruses.

For human infections, diagnostic is carried out in CSF and/or serum samples. In the case of animal infection, other tissues could be used including brain.

Commercial vaccines based on inactivated virus are available for horse vaccination.

Testing of EEEV/WEEV vaccines was performed by intracranial challenge with either EEEV or WEEV; the formalin-inactivated preparations were shown to be highly efficacious in protecting against clinical disease. Since vaccines do not confer long-lasting protection, vaccination against EEEV in the USA is recommended once a year and in areas at high risk, more often (AAEP, online). Since EEEV vaccines are against North American strains, they are not so effective against MADV (Dietz et al., ; Strizki and Repik, ). Horses should be vaccinated twice a year against WEEV due to low immunogenicity (Barber et al., ). Vaccines are administered by injecting 1 mL doses intramuscularly using aseptic techniques. After the first dose, a second one is recommended after 3–4 weeks. Later, yearly vaccination (or more often in case of high risk) is recommended (Arechiga-Ceballos and Aguilar-Setien, ).

No vaccine for human use is available. Only vaccines to be used in horses are commercially distributed but no vaccines have been authorised for use in the European Union by the European Medicine Agency (EMA)

No medical treatment is available for these infections.

Severe clinical disease or death can occur in humans and four laboratory-acquired cases of EEE and seven cases of WEE (with two deaths) have been reported and the recommendation is that to work with these viruses in a biosafety level 3 (BSL3) facility although a lesser biosafety level could be used with diagnostic samples. If viral isolation is tried a BSL3 facility is needed (Anonymous, ). Laboratories with suitable BSL facilities are available throughout Europe. However, access to diagnostic tests is limited.

Due to the route of transmission (infected mosquitoes) of these viruses, biosecurity measures are not a requirement in preventing the pathogen introduction in EU.

No specific recommendation for restrictions of movements for EEEV and/or WEEV infected animals is available. If a case is detected within EU, measures for vector control should be applied trying to reduce vector numbers in an area by treatment and/or elimination of potential breeding sites. Large-scale insecticide spraying is generally too costly, ineffective in the long-term, and/or environmentally unacceptable. Other approaches might be to treat susceptible animals with long acting insecticides during critical periods or remove animals from high-activity insect vector areas either continuously or during times of the day or year when insect vectors are most active. If necessary, zoning and compartmentalisation measures could be applied (OIE, ).

Methods for killing of animals, if necessary, are compiled in (OIE, ), no specific recommendation for EEEV and/or WEEV infected animals are available.

Animal carcasses and products derived from EEEV and/or WEEV infected animals pose a negligible transmission risk so no special measures are warranted (Williams, ).

After the Texas WEE outbreak in 1971, the cost of infection per person was estimated as $320,000 (Earnest et al., ). The economic burden associated with patients suffering long-term sequelae due to EEE was also determined. Hospital costs for the first week of infection were approximately $21,000 but medical costs for someone suffering from long-term sequelae, would exceed $0.4 million per year per individual, with costs reaching up to $3 million in the life span of the affected individual. The cost of insecticidal prevention of mosquito vectors was estimated as $0.7–1.4 million dollars (Villari et al., ).

As a general rule, a horse owner might save about 2 per cent of the annual cost by not inoculating the horse with the core vaccines that includes WEEV and EEEV; however, the cost of not vaccinating can far outweigh the potential savings (Scott, ).

Although no precise data are available for WEEV or EEEV, cost estimations for West Nile virus affecting horses in Texas have been calculated by Galvan and colleagues (Galvan et al., online) and they estimate the cost of vaccination as US$6,250,000 in 2002 and US$6,250,000 in 2003 while costs of mortality of infected horses during 2002 was US$2,856,000 and during 2003 it was US$1,205,400.

No references have been found regarding this item.

One of the measures for control is avoiding mosquito bites and this could imply stabling of animals so regulations should be followed.

Uncontrolled use of insecticides could affect some animal species but strict regulations should be applied in case of need of using these compounds.

Uncontrolled use of insecticides could affect environment and biodiversity but strict regulations should be applied in case of need of using these compounds but no mortality in wild species because of the control measures to be applied is expected.

This section presents the results of the expert judgement on the criteria of Article 5 of the AHL about equine encephalomyelitis (Eastern and Western) (Table ). The expert judgement was based on Individual and Collective Behavioural Aggregation (ICBA) approach described in detail in the opinion on the methodology (EFSA AHAW Panel, ). Experts have been provided with information of the disease fact-sheet mapped into Article 5 criteria (see supporting information, Annex A), based on that the experts indicate their Y/N or ‘na’ judgement on each criterion of Article 5, and the reasoning supporting their judgement.

The minimum number of judges in the judgement was 12. The expert judgement was conducted as described in the methodological opinion (EFSA AHAW Panel, ). For details on the interpretation of the questions see Appendix B of the methodological opinion (EFSA AHAW Panel, ).

Outcome of the expert judgement on the Article 5 criteria for equine encephalomyelitis (Eastern and Western)

Colour code: green = consensus (Yes/No); yellow = no consensus (NC); red = not applicable (na), i.e. insufficient evidence or not relevant to judge.

This section displays the assessment related to each criterion of Article 5 where no consensus was achieved in form of tables (Tables  and ). The proportion of Y, N or na answers are reported, followed by the list of different supporting views for each answer.

Outcome of the expert judgement related to criterion 5 B(iii)

NC: non-consensus; number of judges: 12.

Reasoning supporting the judgement

Supporting Yes:

• Considering the horse sector, if introduced, EEE and WEE may have a high impact due to their epidemic potential and high mortality in horses.
• For the sector of race horses, even a low number of affected animals may result in very high losses in terms of costs.
• Depending on the area where the disease is introduced, there could be a significant impact (i.e. foal markets). Even if one single infected animal is introduced, markets could be closed (France as example).
• There may be a potential significant economic impact considering production of race horses in the absence of control measures (vector control or vaccination).

Supporting No:

• The opinion on vector-borne diseases (EFSA AHAW Panel, ) indicates that the probability of spread in the Union is low due to too low densities of vectors and hosts. Thus, the potential impact can be considered to be low.

Outcome of the expert judgement related to criterion 5 B(v)

NC: non-consensus; number of judges: 12.

Reasoning supporting the judgement

Supporting No:

• The model in the scientific opinion on vector-borne diseases (EFSA AHAW Panel, ) suggests that the impact of these diseases on the environment and biodiversity is likely to be low.

Supporting na:

• Cases in the US are well-known and there is no significant impact, but it is difficult to infer how the disease would behave in completely different ecosystems in the EU.
• There is a lack of information concerning the susceptibility of the European bird population.

As from the legal text of the AHL, a disease is considered eligible to be listed as laid down in Article 5 if it fulfils all criteria of the first set from A(i) to A(v) and at least one of the second set of criteria from B(i) to B(v). According to the assessment methodology (EFSA AHAW Panel, ), a criterion is considered fulfilled when the outcome is ‘Yes’. According to the results shown in Table , equine encephalomyelitis (Eastern and Western) complies with all criteria of the first set and with two criteria of the second set, therefore it is considered eligible to be listed as laid down in Article 5 of the AHL.

This section presents the results of the expert judgement on the criteria of Annex IV referring to categories as in Article 9 of the AHL about equine encephalomyelitis (Eastern and Western) (Tables –). The expert judgement was based on ICBA approach described in detail in the opinion on the methodology. Experts have been provided with information of the disease fact-sheet mapped into Article 9 criteria (see supporting information, Annex A), based on that the experts indicate their Y/N or ‘na’ judgement on each criterion of Article 9, and the reasoning supporting their judgement.

The minimum number of judges in the judgement was 12. The expert judgement was conducted as described in the methodological opinion (EFSA AHAW Panel, ). For details on the interpretation of the questions, see Appendix B of the methodological opinion (EFSA AHAW Panel, ).

Outcome of the expert judgement related to the criteria of Section 1 of Annex IV (category A of Article 9) for equine encephalomyelitis (Eastern and Western)

Colour code: green = consensus (Yes/No); yellow = no consensus (NC); red = not applicable (na), i.e. insufficient evidence or not relevant to judge.

Outcome of the expert judgement related to the criteria of Section 2 of Annex IV (category B of Article 9) for equine encephalomyelitis (Eastern and Western)

Colour code: green = consensus (Yes/No); yellow = no consensus (NC); red = not applicable (na), i.e. insufficient evidence or not relevant to judge.

Outcome of the expert judgement related to the criteria of Section 3 of Annex IV (category C of Article 9) for equine encephalomyelitis (Eastern and Western)

Colour code: green = consensus (Yes/No); yellow = no consensus (NC); red = not applicable (na), i.e. insufficient evidence or not relevant to judge.

Outcome of the expert judgement related to the criteria of Section 4 of Annex IV (category D of Article 9) for equine encephalomyelitis (Eastern and Western)

Colour code: green = consensus (Yes/No); yellow = no consensus (NC).

Outcome of the expert judgement related to the criteria of Section 5 of Annex IV (category E of Article 9) for equine encephalomyelitis (Eastern and Western)

Colour code: green = consensus (Yes/No).

This section displays the assessment related to each criterion of Annex IV referring to the categories of Article 9 of the AHL where no consensus was achieved in form of tables (Tables –). The proportion of Y, N or ‘na’ answers are reported, followed by the list of different supporting views for each answer.

Outcome of the expert judgement related to criterion 5(b) of Article 9

NC: non-consensus; number of judges: 12.

Reasoning supporting the judgement

Supporting Yes:

• If introduced in the EU and in the absence of control measures, the animal welfare impact would be significant.
• High morbidity with severe clinical signs (neurological sequelae) has been described.
• There is potential for significant animal welfare impact. Outbreaks of EEE in horses in North America have been common and often accompanied by high case fatality rates: 80–90% of the infected horses developed acute and lethal disease, and about 66% of the survivors developed neurological sequelae (Scott and Weaver, ). The mortality is lower for WEEV, which generally causes a mild disease but in some cases, symptoms of altered mental status, weakness and signs of meningeal irritation occur and a minority of infected individuals develop encephalitis or encephalomyelitis.

Supporting No:

• The animal welfare impact is not considered to affect large numbers of animals.
• Based on the model as in the scientific opinion on vector-borne diseases (EFSA AHAW Panel, ), the likelihood of animal welfare impact for large numbers in the EU is low.

Supporting na:

• There may be an impact on animal welfare for the affected horses but it is difficult to state that this would be on ‘large numbers’.
• In the USA, there have been large epizootics, but the model in the scientific opinion on vector-borne diseases (EFSA AHAW Panel, ) showed that for EEEV there was a very low to low rate of introduction, and subsequently, a very low extent of annual spread. The latter had high uncertainty due to the high uncertainty related to the efficacy of the control measures to contain the spread. The annual extent of spread of WEEV has not been assessed, as the overall rate of introduction was estimated to be very low (EFSA AHAW Panel, ).

Outcome of the expert judgement related to criterion 5(d) of Article 9

NC: non-consensus; number of judges: 12.

Reasoning supporting the judgement

Supporting No:

• In the scientific opinion on vector-borne diseases (EFSA AHAW Panel, ), the disease spread and impact was not assessed for WEE due to very low rate of introduction and only low extent of spread was assessed for EEE. According to that, there is no significant impact on biodiversity.

Supporting na:

• There is evidence available in the US, but it is difficult to determine how the disease would behave in a different ecosystem in the EU.
• No information is available on susceptibility of wild species (e.g. birds or rodents) in the EU.
• It is uncertain whether there would be an impact with a long-term effect on biodiversity.

Outcome of the expert judgement related to criterion D of Article 9

NC: non-consensus; number of judges: 12.

Reasoning supporting the judgement

Supporting Yes:

• Movement restrictions and regulations on import of reservoir animals (i.e. birds, reptiles, rodents and amphibian) into the EU can reduce the introduction and spread of these infections, although may not be totally effective in preventing it.

Supporting No:

• Controls in imported animals may not be sufficiently effective in totally preventing disease introduction and trade of ornamental birds could pose a serious risk, because the quarantine or testing of these species is not feasible. Movement control measures would not prevent spread of the disease by mosquitoes and wild birds.

As from the legal text of the AHL, a disease is considered fitting in a certain category (A, B, C, D or E corresponding to point (a) to point (e) of Article 9(1) of the AHL) if it is eligible to be listed for Union intervention as laid down in Article 5(3) and fulfils all criteria of the first set from 1 to 2.4 and at least one of the second set of criteria from 3 to 5(d) as shown in Tables –. According to the assessment methodology (EFSA AHAW Panel, ), a criterion is considered fulfilled when the outcome is ‘Yes’.

A description of the outcome of the assessment of criteria in Annex IV for equine encephalomyelitis (Eastern and Western) for the purpose of categorisation as in Article 9 of the AHL is presented in Table .

Outcome of the assessment of criteria in Annex IV for equine encephalomyelitis (Eastern and Western) for the purpose of categorisation as in Article 9 of the AHL

According to the assessment here performed, equine encephalomyelitis (Eastern and Western) complies with the following criteria of the Sections 1–5 of Annex IV of the AHL for the application of the disease prevention and control rules referred to in points (a) to (e) of Article 9(1):

1. To be assigned to category A, a disease needs to comply with all criteria of the first set (1, 2.1–2.4) and according to the assessment equine encephalomyelitis (Eastern and Western) complies with criteria 1, 2.2, 2.3 and 2.4, but not with 2.1. To be eligible for category A, a disease needs to comply additionally with one of the criteria of the second set (3, 4, 5a–d) and equine encephalomyelitis (Eastern and Western) does not comply with criteria 3, 4 and 5a, the assessment is inconclusive on compliance with criteria 5b and 5d and not applicable on criterion 5c.
2. To be assigned to category B, a disease needs to comply with all criteria of the first set (1, 2.1–2.4) and according to the assessment equine encephalomyelitis (Eastern and Western) complies with criteria 2.1, 2.2 and 2.3, but not with criteria 1 and 2.4. To be eligible for category B, a disease needs to comply additionally with one of the criteria of the second set (3, 4, 5a–d) and equine encephalomyelitis (Eastern and Western) does not comply with criteria 3, 4 and 5a, the assessment is inconclusive on compliance with criteria 5b and 5d and not applicable on criterion 5c.
3. To be assigned to category C, a disease needs to comply with all criteria of the first set (1, 2.1-2.4) and according to the assessment equine encephalomyelitis (Eastern and Western) complies with criteria 2.1, 2.2 and 2.3, but not with criteria 1 and 2.4. To be eligible for category C, a disease needs to comply additionally with one of the criteria of the second set (3, 4, 5a–d) and equine encephalomyelitis (Eastern and Western) complies with criteria 3 and 4, but not with criterion 5a, the assessment is inconclusive on compliance with criteria 5b and 5d and not applicable on criterion 5c.
4. To be assigned to category D, a disease needs to comply with criteria of Sections 1, 2, 3 or 5 of Annex IV of the AHL, with which equine encephalomyelitis (Eastern and Western) complies, and with the specific criterion D of Section 4, with which the assessment on equine encephalomyelitis (Eastern and Western) is inconclusive.
5. To be assigned to category E, a disease needs to comply with criteria of Sections 1, 2 or 3 of Annex IV of the AHL and/or the surveillance of the disease is necessary for reasons relating to animal health, animal welfare, human health, the economy, society or the environment. The latter is applicable if a disease fulfils the criteria as in Article 5, with which equine encephalomyelitis (Eastern and Western) complies.

This section presents the results of the assessment on the criteria of Article 8(3) of the AHL about equine encephalomyelitis (Eastern and Western). The Article 8(3) criteria are about animal species to be listed, as it reads below:

‘3. Animal species or groups of animal species shall be added to this list if they are affected or if they pose a risk for the spread of a specific listed disease because:

1. they are susceptible for a specific listed disease or scientific evidence indicates that such susceptibility is likely; or
2. they are vector species or reservoirs for that disease, or scientific evidence indicates that such role is likely'.

For this reason, the assessment on Article 8 criteria is based on the evidence as extrapolated from the relevant criteria of Article 7, i.e. the ones related to susceptible and reservoir species or routes of transmission, which cover also possible role of biological or mechanical vectors. According to the mapping, as presented in Table , Section 3.2 of the scientific opinion on the ad hoc methodology (EFSA AHAW Panel, ), the main animal species to be listed for equine encephalomyelitis (Eastern and Western) according to the criteria of Article 8(3) of the AHL are as displayed in Tables  and .

Main animal species to be listed for Eastern equine encephalomyelitis according to criteria of Article 8 (source: data reported in Sections 3.1.1.1 and 3.1.1.6)

Main animal species to be listed for Western equine encephalomyelitis according to criteria of Article 8 (source: data reported in Sections 3.1.1.1 and 3.1.1.6)

TOR 1: for each of those diseases an assessment, following the criteria laid down in Article 7 of the AHL, on its eligibility of being listed for Union intervention as laid down in Article 5(3) of the AHL;

• According to the assessment here performed, equine encephalomyelitis (Eastern and Western) complies with all criteria of the first set and with two criteria of the second set and therefore can be considered eligible to be listed for Union intervention as laid down in Article 5(3) of the AHL.

TOR 2a: for each of the diseases which was found eligible to be listed for Union intervention, an assessment of its compliance with each of the criteria in Annex IV to the AHL for the purpose of categorisation of diseases in accordance with Article 9 of the AHL;

• According to the assessment here performed, equine encephalomyelitis (Eastern and Western) meets the criteria as in Section 5 of Annex IV of the AHL, for the application of the disease prevention and control rules referred to in point (e) of Article 9(1) of the AHL. According to the assessment here performed, it is inconclusive whether equine encephalomyelitis (Eastern and Western) complies with the criteria as in Section 4 of Annex IV of the AHL, for the application of the disease prevention and control rules referred to in point (d) of Article 9(1) of the AHL. Compliance of equine encephalomyelitis (Eastern and Western) with the criteria as in Section 4 is dependent on a decision on criterion D.

TOR 2b: for each of the diseases which was found eligible to be listed for Union intervention, a list of animal species that should be considered candidates for listing in accordance with Article 8 of the AHL.

• According to the assessment here performed, the animal species that can be considered to be listed for equine encephalomyelitis (Eastern and Western) according to Article 8(3) of the AHL are several species of mammals, birds, reptiles and amphibians as susceptible species; rodents, lagomorphs and several bird species as reservoirs and at least four mosquito species (family Culicidae) as vectors, as reported in Tables  and in Section 3.4 of the present document.

¹⁰⁰⁷Commission Decision 93/197/EEC of 5 February 1993 on animal health conditions and veterinary certification for imports of registered equidae and equidae for breeding and production. OJ L 86, 6.4.1993, p. 16-33.

¹⁰⁰⁸ http://www.ema.europa.eu/ema/

¹⁰⁰⁹A vector is a living organism that transmits an infectious agent from an infected animal to a human or another animal. Vectors are frequently arthropods. Biological vectors may carry pathogens that can multiply within their bodies and be delivered to new hosts, usually by biting. In mechanical vectors the pathogens do not multiply within the vector, which usually remains infected for shorter time than in biological vectors.

• AHAW
• EFSA Panel on Animal Health and Welfare
• AHL
• Animal Health Law
• BHK
• baby hamster kidney
• CDC
• Centers for Disease Control and Prevention
• CF
• complement fixation
• CSF
• cerebrospinal fluid
• DALY
• disability-adjusted life year
• ECHA
• European Chemicals Agency
• EEE
• Eastern Equine Encephalitis
• EEEV
• Eastern Equine Encephalitis virus
• ELISA
• enzyme-linked immunosorbent assay
• EMA
• European Medicine Agency
• ENIVD
• European Network for the Diagnostic of Imported Viral Diseases
• ICBA
• Individual and Collective Behavioural Aggregation
• IgM
• immunoglobulin M
• MADV
• Madariaga virus
• OIE
• World Organization for Animal Health
• PCR
• polymerase chain reaction
• RK
• rabbit kidney
• RT
• reverse-transcription
• ToR
• Terms of Reference
• VEE
• Venezuelan equine encephalitis
• WEE
• Western Equine Encephalitis
• WEEV
• Western Equine Encephalitis virus