- Latest available (Revised)
- Original (As adopted by EU)
Council Directive 2009/156/ECShow full title
Council Directive 2009/156/EC of 30 November 2009 on animal health conditions governing the movement and importation from third countries of equidae (codified version) (Text with EEA relevance)
You are here:
- Directives originating from the EU
- 2009 No. 156
- Annexes only
What Version
Advanced Features
- Show Geographical Extent(e.g. England, Wales, Scotland and Northern Ireland)
- Show Timeline of Changes
More Resources
Revised version PDFs
- Revised 18/10/20160.45 MB
- Revised 01/07/20130.44 MB
Legislation originating from the EU
When the UK left the EU, legislation.gov.uk published EU legislation that had been published by the EU up to IP completion day (31 December 2020 11.00 p.m.). On legislation.gov.uk, these items of legislation are kept up-to-date with any amendments made by the UK since then.
This item of legislation originated from the EU
Legislation.gov.uk publishes the UK version. EUR-Lex publishes the EU version. The EU Exit Web Archive holds a snapshot of EUR-Lex’s version from IP completion day (31 December 2020 11.00 p.m.).
Status:
EU Directives are published on this site to aid cross referencing from UK legislation. Since IP completion day (31 December 2020 11.00 p.m.) no amendments have been applied to this version.
ANNEX IU.K. COMPULSORILY NOTIFIABLE DISEASES
The following diseases are compulsorily notifiable:
Dourine
Glanders
Equine encephalomyelitis (of all types, including VEE)
Infectious anaemia
Rabies
Anthrax
African horse sickness
Vesicular stomatitis
ANNEX IIU.K.MODEL HEALTH ATTESTATION (1)
Passport No …
I, the undersigned, certify that(2) the animal identified above meets the following requirements:
(a)
it has been examined today and shows no clinical sign of disease;
(b)
it is not intended for slaughter under a national programme of contagious or infectious disease eradication;
(c)
it does not come from the territory or part of the territory of a Member State which is the subject of restrictions for reasons of African horse sickness, or
it comes from the territory or part of the territory of a Member State which was subject to prohibition for animal health reasons and has undergone, with satisfactory results, the tests provided for in Article 5(5) of Directive 2009/156/EC in the quarantine station of … between …and…(3)
it is not vaccinated against African horse sickness, or,
it was vaccinated against African horse sickness on …(3) (4);
(d)
it has not come from a holding which was subject to prohibition for animal health reasons nor had contact with equidae from a holding which was subject to prohibition for animal health reasons:
during six months in the case of equidae suspected of having contracted dourine, beginning on the date of the last actual or possible contact with a sick animal. However, in the case of a stallion, the prohibition shall apply until the animal is castrated,
during six months in the case of glanders or equine encephalomyelitis, beginning on the day on which the equidae suffering from the disease in question are slaughtered,
in the case of infectious anaemia, until the date on which, the infected animals having been slaughtered, the remaining animals have shown a negative reaction to two Coggins tests carried out three months apart,
during six months from the last case, in the case of vesicular stomatitis,
during one month from the last case, in the case of rabies,
during 15 days from the last case, in the case of anthrax,
if all the animals of species susceptible to the diseases located on the holding have been slaughtered and the premises disinfected during 30 days, beginning on the day on which the animals were destroyed and the premises disinfected, except in the case of anthrax, where the period of prohibition is 15 days;
(e)
to the best of my knowledge, it has not been in contact with equidae suffering from an infectious or contagious disease in the 15 days prior to this declaration;
ANNEX IIIU.K.MODEL HEALTH CERTIFICATE For trade between Member States EQUIDAE
[F1ANNEX IV U.K. AFRICAN HORSE SICKNESS DIAGNOSIS
Textual Amendments
PART A U.K. Serological tests
The serological method described hereinafter are enzyme-linked immunosorbent assays (ELISA) based on point 2 of Section B in Chapter 2.5.1 of the Manual of Diagnostic Tests and Vaccines for Terrestrial Animals, Edition 2016 as adopted by the World Assembly of Delegates of the OIE in May 2012.
The VP7 viral protein is an immuno-dominant major antigen of the African horse sickness virus (AHSV) and is conserved across the nine AHSV serotypes. Recombinant AHSV-VP7 proteins have been shown to be stable and innocuous and suitable to be used as antigens in ELISA procedures for determination of AHSV antibodies with a high degree of sensitivity and specificity (Laviada et al., 1992b (6) ; Maree and Paweska, 2005). The indirect ELISA and the blocking ELISA are the two AHS-VP7 ELISA tests suitable for serological diagnosis of African horse sickness (AHS).
1. Indirect ELISA for the detection of antibodies to African horse sickness virus (AHSV) U.K.
The conjugate used in this method is a horseradish peroxidase anti-horse gamma-globulin reacting with the serum of horses, mules and donkeys. The method described by Maree & Paweska (2005) (7) uses protein G as conjugate that also reacts with zebra serum.
The antigen may be provided by the Centro de Investigación en Sanidad Animal (CISA), Spain, within 4 to 6 months of request.
1.1. Test procedure U.K.
1.1.1. Solid phase U.K.
1.1.1.1. Coat ELISA plates with recombinant AHSV-4 VP7 diluted in carbonate/bicarbonate buffer, pH 9,6. Incubate plates overnight at 4 °C. U.K.
1.1.1.2. Wash the plates five times with distilled water containing 0,01 % (v/v) Tween 20 (washing solution). Gently tap the plates onto absorbent material to remove any residual wash. U.K.
1.1.1.3. Block the plates with phosphate buffered saline (PBS) pH 7,2 + 5 % (w/v) skimmed milk (Nestlé Dry Skim Milk TM ), 200 μl/well, for 1 hour at 37 °C. U.K.
1.1.1.4. Remove the blocking solution and gently tap the plates onto absorbent material. U.K.
1.1.2. Test samples U.K.
1.1.2.1. Serum samples to be tested, and positive and negative control sera, are diluted 1 in 25 in PBS + 5 % (w/v) skimmed milk + 0,05 % (v/v) Tween 20, 100 μl per well. Incubate for 1 hour at 37 °C. U.K.
For titration, make a twofold dilution series from 1 in 25 (100 μl/well), one serum per plate column, and do the same with positive and negative controls. Incubate for 1 hour at 37 °C.
1.1.2.2. Wash the plates five times with distilled water containing 0,01 % (v/v) Tween 20 (washing solution). Gently tap the plates onto absorbent material to remove any residual wash. U.K.
1.1.3. Conjugate U.K.
1.1.3.1. Dispense 100 μl/well of horseradish-peroxidase (HRP) -conjugated anti-horse gamma-globulin diluted in PBS + 5 % milk + 0,05 % Tween 20, pH 7,2. Incubate for 1 hour at 37 °C. U.K.
1.1.3.2. Wash the plates five times with distilled water containing 0,01 % (v/v) Tween 20 (washing solution). Gently tap the plates onto absorbent material to remove any residual wash. U.K.
1.1.4. Chromogen/Substrate U.K.
1.1.4.1. Add 200 μl/well of chromogen/substrate solution (10 ml of 80,6 mM DMAB (dimethyl aminobenzaldehyde) + 10 ml of 1,56 mM MBTH (3-methyl-2-benzo-thiazoline hydrazone hydrochlorid) + 5 μl H 2 O 2 ). U.K.
Colour development is stopped by adding 50 μl of 3N H 2 SO 4 after approximately 5 to 10 minutes (before the negative control begins to be coloured).
Other chromogens such as ABTS (2,2′-Azino-bis-[3-ethylbenzothiazoline-6-sulphonic acid]), TMB (tetramethyl benzidine), or OPD (ortho-phenyldiamine) can also be used.
1.1.4.2. Read the plates at 600 nm (or 620 nm). U.K.
1.2. Interpretation of the results U.K.
1.2.1. Calculate the cut-off value by adding 0,06 to the value of the negative control (0,06 is the standard deviation derived with a group of 30 negative sera). U.K.
1.2.2. Test samples giving absorbance values lower than the cut-off are regarded as negative. U.K.
1.2.3. Test samples giving absorbance values greater than the cut-off + 0,15 are regarded as positive. U.K.
1.2.4. Test samples giving intermediate absorbance values are considered to be inconclusive and a second technique must be employed to confirm the result. U.K.
2. Blocking ELISA for the detection of antibodies to African horse sickness virus (AHSV) U.K.
The competitive blocking ELISA is designed to detect specific AHSV antibodies in sera from animals of any equine species, i.e. horses, donkeys, zebra and their crosses, preventing the problem of specificity experienced occasionally using the indirect ELISAs.
The principle of the test is the blocking of the reaction between the recombinant VP7 protein absorbed to the ELISA plate and a conjugated AHS-VP7 specific monoclonal antibody (Mab). Antibody in the test sera will block the reaction between the antigen and the Mab resulting in a reduction in colour. Because the Mab is directed against the VP7, the assay will give a high level of sensitivity and specificity.
The competitive blocking ELISA is commercially available.
2.1. Test procedure U.K.
2.1.1. Solid Phase U.K.
2.1.1.1. Coat ELISA plates with 50-100 ng of recombinant AHSV-4 VP7 diluted in carbonate/bicarbonate buffer, pH 9,6. Incubate overnight at 4 °C. U.K.
2.1.1.2. Wash the plates three times with phosphate buffered saline (PBS) 0,1× containing 0,135 M NaCl and 0,05 % (v/v) Tween 20 (PBST). Gently tap the plates on to absorbent material to remove any residual wash. U.K.
2.1.2. Test samples and controls U.K.
2.1.2.1. Serum samples to be tested, and positive and negative control sera, are diluted 1 in 5 in diluent containing 0,35 M NaCl, 0,05 % (v/v) Tween 20 and 0,1 % Kathon, 100 μl per well. Incubate for 1 hour at 37 °C. U.K.
For titration, make a twofold dilution series of the test sera from 1 in 10 to 1 in 280 across 8 wells (100 μl/well), one serum per plate column, and do the same with positive and negative controls. Incubate for 1 hour at 37 °C.
2.1.2.2. Wash the plates five times with phosphate buffered saline (PBS) 0,1× containing 0,135 M NaCl and 0,05 % (v/v) Tween 20 (PBST). Gently tap the plates on to absorbent material to remove any residual wash. U.K.
2.1.3. Conjugate U.K.
2.1.3.1. Dispense 100 μl/well of horseradish peroxidase-conjugated Mab anti-VP7. In advance, this Mab has been diluted 1/ 5 000 -1/ 15 000 in a 1/1 solution of StabiliZyme Select® Stabilizer (SurModics. Reference: SZ03) in distilled water. Incubate for 30 minutes at 37 °C. U.K.
2.1.3.2. Wash the plates five times with phosphate buffered saline (PBS) 0,1× containing 0,135 M NaCl and 0,05 % (v/v) Tween 20 (PBST). Gently tap the plates on to absorbent material to remove any residual wash. U.K.
2.1.4. Chromogen/Substrate U.K.
Add 100 μl/well chromogen/substrate solution, i.e. 1 ml of ABTS (2,2′-Azino-bis-[3-ethylbenzothiazoline-6-sulphonic acid]) 5 mg/ml + 9 ml of substrate buffer (0,1 M Phosphate-Citrate buffer of pH 4 containing 0,03 % H 2 O 2 ), and incubate for 10 minutes at room temperature. Colour development is stopped by adding 100 μl/well of 2 % (w/v) SDS (sodium dodecyl sulphate).
2.1.5. Reading U.K.
Read at 405 nm in an ELISA reader.
2.2. Interpretation of the results U.K.
2.2.1. Determine the blocking percentage (BP) of each sample by applying the following formula, where ‘Abs’ stands for antibodies: U.K.
2.2.2. Samples showing a BP value higher than 50 % should be considered as positive for AHSV antibodies. U.K.
2.2.3. Samples showing a BP value lower than 45 % should be considered as negative for AHSV antibodies. U.K.
2.2.4. Samples showing a BP value between 45 % and 50 % should be considered as inconclusive and must be retested. If the result is again inconclusive, the animals should be retested on samples taken not earlier than two weeks after the sample which was considered to be inconclusive was taken. U.K.
PART B U.K. Identification of the agent
Real-time Reverse-Transcription Polymerase Chain Reaction (rRT-PCR) U.K.
Agent identification tests based on nucleic acid methods must detect reference strains from the nine virus serotypes of the AHSV.
The method described in point 2.1 is based on point 1.2 of Section B in Chapter 2.5.1 of the Manual of Diagnostic Tests and Vaccines for Terrestrial Animals, Edition 2016 as adopted by the World Assembly of Delegates of the OIE in May 2012.
Any RT-PCR detection method used for the testing of samples, either blood or spleen, in the context of Directive 2009/156/EC must perform equal to or exceed the sensitivity of the methodologies described in point 2.
Inactivated virus of serotypes 1 to 9 reference strains may be obtained from the European Union Reference Laboratory or the OIE Reference Laboratory for African horse sickness, Algete, Spain.
1. Extraction of viral RNA U.K.
To assure a good reaction it is necessary to extract from the sample an AHSV RNA of high quality. The extraction of nucleic acids from clinical samples can be performed by a variety of in-house and commercially available methods.
Commercial kits use different approaches for RNA isolation. Most are based on one of the following procedures:
Phenol-chloroform extraction of nucleic acids;
Adsorption of nucleic acids to filter system;
Adsorption of nucleic acids to magnetic beads system.
An example of an in-house RNA extraction is given below:
1.1.
1 g of tissue sample is homogenised in 1 ml of denaturing solution (4 M guanidium thiocyanate, 25 mM sodium citrate, 0,1 M 2-mercaptoethanol, 0,5 % sarcosyl).
1.2.
After centrifugation, 1 μg of yeast RNA, 0,1 ml of 2 M sodium acetate pH 4, 1 ml of phenol and 0,2 ml of chloroform/isoamyl alcohol mixture (49/1) are added to the supernatant.
1.3.
The suspension is vigorously shaken and cooled on ice for 15 minutes.
1.4.
After centrifugation, the RNA present in the aqueous phase is phenol extracted, ethanol precipitated and resuspended in sterile water.
2. Real-time RT-PCR Procedure U.K.
2.1. Group-specific real-time RT-PCR by Agüero et al., 2008 (8) U.K.
This group-specific real-time RT-PCR targets VP7 of the AHSV and is able to detect all known AHSV serotypes and strains currently circulating. It has been employed with very good results by the participating national reference laboratories of the European Union Member States in the proficiency tests annually organised by the European Union Reference Laboratory for the period 2009-2015. Moreover, in an international ring trial organised in 2015 in the framework of the OIE reference laboratories network this protocol was ranked very high amongst others.
Primer and probe sequences for the detection of AHSV species viruses:
— forward Primer
5′-CCA-GTA-GGC-CAG-ATC-AAC-AG-3′
— reverse Primer
5′-CTA-ATG-AAA-GCG-GTG-ACC-GT-3′
— MGB-TaqMan probe
5′-FAM-GCT-AGC-AGC-CTA-CCA-CTA-MGB-3′
2.1.1.
Primer stock concentration is diluted to a working concentration of 8 μM ( ‘ primer working stock 8 μM ’ ) whereas probe is diluted to a working concentration of 50 μM ( ‘ probe working stock 50 μM ’ ). A test plate layout should be designed and loaded into the real time PCR machine software. Using the layout as a guide, 2,5 μl of each primer working stock 8 μM is added to each well that will contain RNA samples, positive and/or negative controls (final concentration of the primer will be 1 μM in the 20 μl RT-PCR mix). The plate is held on ice.
2.1.2.
2 μl of isolated RNA (test samples and positive control), or 2 μl of RNAse-free water in negative reaction controls, is mixed with forward and reverse primers. This mixture is denatured by heating at 95 °C for 5 minutes, followed by rapid cooling on ice for at least 5 minutes.
2.1.3.
An appropriate volume of real time one-step RT-PCR master mix for the number of samples to be tested is prepared following manufacturer's instructions. 0,1 μl of probe working stock 50 μM is added to each well containing RNA samples (final concentration of the probe will be 0,25 μM in each well containing RNA samples). 13 μl of real time one-step RT-PCR master mix is distributed in each well on the PCR plate containing the denatured primers and RNA.
2.1.4.
The plate is placed in a real time thermal cycler programmed for reverse transcription and cDNA amplification/fluorescence detection. Amplification conditions consist of a first reverse-transcription step at 48 °C for 25 minutes, followed by 10 minutes at 95 °C ( ‘ hot start ’ ) and 40 cycles of 15 seconds at 95 °C, 35 seconds at 55 °C and 30 seconds at 72 °C (or 40 cycles at 97 °C for 2 seconds and 55 °C for 30 seconds if reagents and thermocycler allowing fast reactions are used). Fluorescence data are acquired at the end of the 55 °C step.
2.1.5.
The assay is considered not valid if atypical amplification curves are obtained, and must be repeated.
Samples are considered positives, if the Ct value (cycle number at which the fluorescence generated within a reaction crosses the fluorescence threshold) is lower than or equal to the defined Ct threshold (35) within 40 PCR cycles (Ct ≤ 35).
Samples are considered inconclusive, if the Ct value is higher than the defined Ct threshold (35) within 40 PCR cycles (Ct > 35).
Samples are considered negative, if a horizontal amplification curve is obtained which does not cross the threshold line within 40 PCR cycles.
2.2. Group-specific real-time RT-PCR by Guthrie et al., 2013 (9) U.K.
Real-time RT-PCR using fluorescence resonance energy transfer (FRET) probes to detect nucleic acid of AHSV.
The AHSV RT-PCR assay described was designed using sequences from a wide variety of currently circulating field strains of AHSV (Quan et al., 2010 (10) ). It also incorporates a proprietary synthetic external control assay to verify proper functioning of the assay components.
Kits for the one-step real-time PCR are available commercially. Below are some basic steps as described by Guthrie et al. (2013), which can be modified depending upon local/case-specific requirements, kits used and equipment available.
Primer and probe sequences for the detection of AHSV species viruses:
— forward Primer
5′-AGA-GCT-CTT-GTG-CTA-GCA-GCC-T-3′
— reverse Primer
5′-GAA-CCG-ACG-CGA-CAC-TAA-TGA-3′
— MGB-TaqMan probe
5′-FAM-TGC-ACG-GTC-ACC-GCT-MGB-3′
2.2.1.
Primer and probe mix stock solutions are made up in a 25× concentration at 5 μΜ for the forward and reverse primers and 3 μΜ for the probe. A test plate layout should be designed and loaded into the real-time PCR machine software. Using the layout as a guide, 5 μl of RNA samples, including test samples and positive and negative controls, are added to appropriate wells of the plate following the layout.
2.2.2.
The RNA is denatured by heating at 95 °C for 5 minutes, followed by rapid cooling on ice for at least 3 minutes.
2.2.3.
An appropriate volume of real-time one-step RT-PCR master mix for the number of samples to be tested is prepared, following the manufacturer's instructions. 1 μl of 25× primer probe mix stock solution (from point 2.2.1 above) is included in the master mix to give a final concentration in each well of 200 nM for each primer and 120 nM of the probe. 20 μl of the master mix is distributed in each well on the PCR plate containing the denatured RNA.
2.2.4.
The plate is placed in a real-time thermal cycler programmed for reverse transcription and cDNA amplification/fluorescence detection as suggested by the manufacturers. Amplification conditions consist of, for example, a first reverse-transcription step at 48 °C for 10 minutes, followed by 10 minutes at 95 °C and 40 cycles of 15 seconds at 95 °C and 45 seconds at 60 °C.
2.2.5.
Samples are considered positives, if the normalised fluorescence for the AHSV RT-PCR assay exceeds a 0,1 threshold within 36 PCR cycles in all replicates of a sample.
Samples are considered inconclusive, if the normalised fluorescence for the AHSV RT-PCR assay exceeds a 0,1 threshold between 36 and 40 PCR cycles in any replicate of a sample.
Samples are considered negative, if the normalised fluorescence for the AHSV RT-PCR assay did not exceed a 0,1 threshold within 40 PCR cycles in all replicates of a sample and if the normalised fluorescence for the proprietary synthetic external control assay exceeded a 0,1 threshold within 33 PCR cycles.]
ANNEX VU.K.
PART AU.K.
Repealed Directive with list of its successive amendments
(referred to in Article 22)
| Council Directive 90/426/EEC | |
| Council Directive 90/425/EEC | only Article 15(3) |
| Council Directive 91/496/EEC | only as regards the reference to Directive 90/426/EEC in Article 26(2) |
| Commission Decision 92/130/EEC | |
| Council Directive 92/36/EEC | only Article 1 |
| 1994 Act of Accession, Annex I, Point V.E.I.A.3 | |
| Commission Decision 2001/298/EC | only as regards the reference to Directive 90/426/EEC in Article 1(1), and Annex I, pt. 2 |
| Commission Decision 2002/160/EC | |
| Council Regulation (EC) No 806/2003 | only Annex III, point 10 |
| 2003 Act of Accession, Annex II, Point 6.B.I.16 | |
| Council Directive 2004/68/EC | only Article 15 |
| Council Directive 2006/104/EC | only Annex, point I.2. |
| Council Directive 2008/73/EC | only Article 7 |
PART BU.K.
List of time-limits for transposition into national law
(referred to in Article 22)
| Directive | Time-limit for transposition |
|---|---|
| 90/426/EEC | 1 January 1992 |
| 90/425/EEC | 1 July 1992 |
| 91/496/EEC | 1 July 1992 |
| 92/36/EEC | 31 December 1992 |
| 2004/68/EC | 19 November 2005 |
| 2006/104/EC | 1 January 2007 |
| 2008/73/EC | 1 January 2010 |
ANNEX VIU.K.
Correlation Table
| Directive 90/426/EEC | This Directive |
|---|---|
| Article 1 | Article 1 |
| Article 2(a) and (b) | Article 2(a) and (b) |
| Article 2(c) | Article 2(c)(i) and (ii) |
| Article 2(d) to (i) | Article 2(d) to (i) |
| Article 3 | Article 3 |
| Article 4(1), (2) and (3) | Article 4(1), (2) and (3) |
| Article 4(4)(i) and (ii) | Article 4(4)(a) and (b) |
| Article 4(5)(a), first to sixth indents | Article 4(5)(a)(i) to (vi) |
| Article 4(5)(b) | Article 4(5)(b) |
| Article 4(6), first subparagraph, first to eighth indents | Article 4(6), first subparagraph, (a) to (h) |
| Article 4(6), second and third subparagraphs | Article 4(6), second and third subparagraphs |
| Article 5(1) | Article 5(1) |
| Article 5(2)(a) | Article 5(2), first subparagraph, (a) and (b) |
| Article 5(2)(b) | Article 5(2), second subparagraph, (a) and (b) |
| Article 5(2)(c) | Article 5(3) |
| Article 5(2)(d) | Article 5(4) |
| Article 5(3)(a) and (b) | Article 5(5)(a) and (b) |
| Article 5(3)(c), first and second indents | Article 5(5)(c), first subparagraph, (i) and (ii) |
| Article 5(3)(c), second indent, last sentence | Article 5(5)(c), second subparagraph |
| Article 5(3)(d) and (e) | Article 5(5)(d) and (e) |
| Article 6 | Article 6 |
| Article 7 | Article 7 |
| Article 8(1), first subparagraph, first and second indents | Article 8(1)(a) and (b) |
| Article 8(1), second subparagraph | Article 8(2) |
| Article 8(2) | Article 8(3) |
| Article 9 | Article 9 |
| Article 10 | Article 10 |
| Article 11(1) | Article 11 |
| Article 11(2) | — |
| Article 12 | Article 12 |
| Article 13 | Article 13 |
| Article 14 | Article 14 |
| Article 15 | Article 15 |
| Article 16(1)(a) to (f) | Article 16(1)(a) to (f) |
| Article 16(1), final sentence | — |
| Article 16(2) | Article 16(2) |
| Article 17 | Article 18 |
| Article 18 | Article 17 |
| Article 19(i) to (iv) | Article 19(a) to (d) |
| Article 22 | — |
| Article 23 | Article 20 |
| Article 24(1) and (2) | Article 21(1) and (2) |
| Article 24(3) | — |
| Article 25(1) and (2) | Article 21(1) and (3) |
| Article 26 | — |
| Article 27 | — |
| — | Article 22 |
| — | Article 23 |
| Article 28 | Article 24 |
| Annex A | Annex I |
| Annex B | Annex II |
| Annex C | Annex III |
| Annex D | Annex IV |
| — | Annex V |
| — | Annex VI |
(1)
This attestation is not required where there is a bilateral agreement in accordance with Article 6 of Directive 2009/156/EC.
(2)
Valid for 10 days.
(3)
Delete whichever does not apply.
(4)
The vaccination date must be entered in the passport.
(5)
This statement does not exempt transporters from their obligations in accordance with Community provisions in force in particular regarding the fitness of animals to be transported.
(6)
[F1Laviada M.D., Roy P. and Sanchez-Vizcaino J.M (1992b). Adaptation and evaluation of an indirect ELISA and immunoblotting test for African horse sickness antibody detection. In: Bluetongue, African Horse Sickness and Related Orbiviruses: Proceedings of the Second International Symposium. Walton T.E. & Osburn B.l., Eds. CRC Press, Boca Raton, Florida, USA, 646-650.]
(7)
[F1Maree S. and Paweska J.T. (2005). Preparation of recombinant African horse sickness virus VP7 antigen via a simple method and validation of a VP7-based indirect ELISA for the detection of group-specific IgG antibodies in horse sera. J. Virol. Methods, 125 (1), 55-65.]
(8)
[F1Agüero M., Gomez-Tejedor C., Angeles Cubillo M., Rubio C., Romero E. and Jimenez-Clavero A. (2008). Real-time fluorogenic reverse transcription polymerase chain reaction assay for detection of African horse sickness virus. J. Vet. Diagn. Invest., 20, 325-328.]
(9)
[F1Guthrie AJ, MacLachlan NJ, Joone C, Lourens CW, Weyer CT, Quan M, Monyai MS, Gardner IA. Diagnostic accuracy of a duplex real-time reverse transcription quantitative PCR assay for detection of African horse sickness virus. Journal of Virological Methods. 2013;189(1):30-5.]
(10)
[F1Quan, M., Lourens, C.W., MacLachlan, N.J., Gardner, I.A., Guthrie, A.J., 2010. Development and optimisation of a duplex real-time reverse transcription quantitative PCR assay targeting the VP7 and NS2 genes of African horse sickness virus. J. Virol. Methods 167, 45-52.]
Options/Help
Print Options
PrintThe Whole Directive
PrintThe Annexes only
Legislation is available in different versions:
Latest Available (revised):The latest available updated version of the legislation incorporating changes made by subsequent legislation and applied by our editorial team. Changes we have not yet applied to the text, can be found in the ‘Changes to Legislation’ area.
Original (As adopted by EU): The original version of the legislation as it stood when it was first adopted in the EU. No changes have been applied to the text.
See additional information alongside the content
Geographical Extent: Indicates the geographical area that this provision applies to. For further information see ‘Frequently Asked Questions’.
Show Timeline of Changes: See how this legislation has or could change over time. Turning this feature on will show extra navigation options to go to these specific points in time. Return to the latest available version by using the controls above in the What Version box.
Opening Options
Different options to open legislation in order to view more content on screen at once
More Resources
Access essential accompanying documents and information for this legislation item from this tab. Dependent on the legislation item being viewed this may include:
- the original print PDF of the as adopted version that was used for the EU Official Journal
- lists of changes made by and/or affecting this legislation item
- all formats of all associated documents
- correction slips
- links to related legislation and further information resources
Timeline of Changes
This timeline shows the different versions taken from EUR-Lex before exit day and during the implementation period as well as any subsequent versions created after the implementation period as a result of changes made by UK legislation.
The dates for the EU versions are taken from the document dates on EUR-Lex and may not always coincide with when the changes came into force for the document.
For any versions created after the implementation period as a result of changes made by UK legislation the date will coincide with the earliest date on which the change (e.g an insertion, a repeal or a substitution) that was applied came into force. For further information see our guide to revised legislation on Understanding Legislation.
More Resources
Use this menu to access essential accompanying documents and information for this legislation item. Dependent on the legislation item being viewed this may include:
- the original print PDF of the as adopted version that was used for the print copy
- correction slips
Click 'View More' or select 'More Resources' tab for additional information including:
- lists of changes made by and/or affecting this legislation item
- confers power and blanket amendment details
- all formats of all associated documents
- links to related legislation and further information resources
All content is available under the Open Government Licence v3.0 except where otherwise stated. This site additionally contains content derived from EUR-Lex, reused under the terms of the Commission Decision 2011/833/EU on the reuse of documents from the EU institutions. For more information see the EUR-Lex public statement on re-use.