Original
Article
Emergency evaluation for existing vaccine against recently isolated Foot
and mouth disease virus type SAT2 in Egypt 2018
Evaluación de emergencia de una vacuna existente
contra el virus de la fiebre aftosa tipo SAT2, aislado recientemente en Egipto
en el 2018
Abousenna MS* ORCID: https://orcid.org/0000-0003-2202-9544
Central Laboratory for Evaluation of Veterinary Biologics, Agricultural
Research Center, P.O. Box 131, 11381, Cairo, Egypt. Cairo, Egypt.
Corresponding
author: mohamedsamy2020@hotmail.com
ABSTRACT
Foot
and mouth disease virus is a highly infectious and contagious pathogen.
Recently the topotype VII, Lib‐12 lineage of serotype SAT2 was reported through
outbreaks in Egypt during 2018. Vaccination is an effective way to control and
combat the foot and mouth disease virus outbreaks especially in endemic areas
like Egypt. The present study was aimed to evaluate the efficacy of the current
produced foot and mouth disease vaccine, against the recently isolated field
strain foot and mouth disease virus SAT2 topotype VII, Lib-12 lineage (SAT2
Libya), by applying in vitro and in vivo studies. Two batches of the
current foot and mouth disease virus vaccine were inoculated in calves. At the
28th day post-vaccination serum samples were collected and tested
against tissue culture adapted foot and mouth disease virus SAT2 Libya and SAT2/EGY/2/2012
using virus neutralization test to determine serological relationship
(r1-value). The challenge test for vaccinated calves was carried out against
the virulent foot and mouth disease virus SAT2 Libya. It was found that
neutralizing antibody titers induced by the two vaccine batches (1 and 2) and
those in unvaccinated animals were 0.48, 0.39 and 0.15 log10 TCID50/mL,
respectively, while the challenge revealed protection values of 20%, 0% and 0%,
respectively. Furthermore, the r1 values were 0.195 and 0.186 for vaccine
batches (1 and 2), respectively. It was concluded that the available local
commercial inactivated foot and mouth disease virus vaccine batches (SAT2
SAT2/EGY/2/2012) are unable to protect calves against the current circulating foot
and mouth disease virus field isolate SAT2 topotype VII, Lib-12 lineage, thus
it is highly recommended to update the existing vaccines with the present
isolated strain.
Keywords: Foot-and-Mouth Disease; vaccine potency; livestock; serogroup.
RESUMEN
El
virus de la fiebre aftosa es un patógeno altamente infeccioso y contagioso.
Recientemente, el topotipo VII, linaje Lib-12 del serotipo SAT2 se describió en
brotes en Egipto durante 2018. La vacunación es una forma eficaz de controlar y
combatir los brotes del virus de la fiebre aftosa, especialmente en áreas
endémicas como Egipto. El presente estudio tuvo como objetivo evaluar la
eficacia de la vacuna contra la fiebre aftosa que se produce actualmente,
frente a la cepa de campo recientemente aislada del virus de la fiebre aftosa
SAT2 topotipo VII, linaje Lib-12 (SAT2 Libia), mediante la aplicación de
estudios in vitro e in vivo. Se inocularon en terneros, dos
lotes de la vacuna actual contra el virus de la fiebre aftosa. A los 28 días
posteriores a la vacunación, se recolectaron muestras de suero y se analizaron
contra el virus de la fiebre aftosa SAT2 Libia adaptado a cultivo de tejidos y
SAT2/EGY/2/2012 utilizando una prueba de neutralización viral para determinar
la relación serológica (valor r1). El ensayo de reto en terneros vacunados se
llevó a cabo empleando una cepa virulenta de la fiebre aftosa SAT2 Libia. Se
encontró que los títulos de anticuerpos neutralizantes inducidos por los dos
lotes de vacuna (1 y 2) y los de animales no vacunados, fueron 0,48, 0,39 y
0,15 log10 DICT50/mL, respectivamente, mientras que la
prueba reveló valores de protección de 20%, 0% y 0%, respectivamente. Además,
los valores de r1 fueron 0,195 y 0,186 para los lotes de vacuna (1 y 2),
respectivamente. Se llegó a la conclusión de que los lotes de vacunas locales
comerciales inactivadas disponibles actualmente (SAT2 SAT2/EGY/2/2012) no
protegen a los terneros contra el virus circulante de la fiebre aftosa SAT2
topotipo VII, linaje Lib-12 que se aisló recientemente, por lo que es
recomendable actualizar las vacunas existentes con la cepa aislada actualmente.
Palabras clave: Fiebre aftosa; potencia de la
vacuna; ganado; serogrupo.
Recibido:10 de junio de 2021
Aceptado: 16 de septiembre de 2021
Introduction
Foot
and mouth disease virus (FMDV) is a highly infectious and contagious pathogen
that infects cloven-hooved livestock and wildlife species and influences
economic and animal welfare grounds.(1)
FMDV belongs to the Aphthovirus
genus, Picornaviridae family.(2) It spreads by direct or indirect contact with infected animals and their
secretions or by contaminated feed. Airborne transmission can occur over
extensive distances by infectious aerosols (droplets).(3,4)
Egypt
is endemic for FMDV from 1950 onward. Three FMDV serotypes: O, A and
South-Africa territories-2 (SAT2) have been reported and circulated in the
field till now. O serotype has a long history of causing regular outbreaks in
Egypt and it is the dominant strain. In 2006, an East African type A strain was
introduced and reported in Egypt.(5) In 2012-2013, the A serotype of Asian
topotype related to Iran genotype was reported,(6) also in 2012,(7)
the FMDV SAT2 topotype VII was recorded in Egypt. Recently, topotype East
Africa 3 (EA‐3), genotype IV (African topotype) and Lib‐12 lineage (topotypes
VII) strains of serotypes O, A and SAT2 were reported, respectively. The
topotype VII, Lib‐12 lineage of serotype SAT2 was reported in outbreaks during
2018.(8,9)
Vaccination
is the effective tool to control and combat the FMDV outbreaks, especially in
endemic areas like Egypt. The available trivalent inactivated FMDV vaccine
(serotype O, topotype Middle East-South Africa, Panasia2 lineage; serotype A,
Asian topotype, Iran05 lineage; and serotype SAT2, topotype VII, Gharbia12
lineage) is produced locally and used in vaccination campaigns in Egypt.(10)
The
efficacy of available FMDV vaccines against the newly isolated field strain
FMDV SAT2 topotype VII, Lib-12 lineage (SAT2 Libya), needs to be determined
because recent circulating field isolates exhibit genomic variation in relation
to the vaccinal strain (SAT2) and FMDV serotypes don’t confer complete cross
protection against sub-serotypes and newly isolated field strains;(8,9)
therefore, in the present work, in vitro
and in vivo studies are carried out,
to know to what extent current locally produced vaccines can protect calves
against the recently isolated strain.
Materials and Methods
Virus
FMDV serotype SAT2,
topotype VII, Lib-12 lineage (SAT2 Libya) was isolated and identified at the
Animal Health Research Institute by Real time polymerase chain reaction
(RT-PCR)(9) and it was officially supplied to the Central
Laboratory for Evaluation of Veterinary Biologics (CLEVB) to be used in the
evaluation of the available inactivated FMDV vaccine. This virus was adapted on
BHK21 cell line having a titer of 104 TCID50/ml to be
used for virus neutralization test (VNT) and as a virulent virus for the
challenge test of experimentally vaccinated calves. FMDV SAT2, topotype VII,
Gharbia12 lineage (SAT2/EGY/2/2012) was supplied by the Strain Bank Department
at CLEVB to be used for FMDV vaccine evaluation according to OIE.(11)
Vaccine
Local commercial trivalent
oil inactivated FMDV vaccine batches (n=2) produced in Egypt and prepared from
local isolate serotypes O/EGY/4/2012, A/EGY/1/2012 and SAT2/EGY/2/2012 were
used in this study. The available vaccine batches were previously evaluated
with satisfactory results by CLEVB, these data are available and compared with
current results.
Calves and experimental design
Fourteen calves (local
breed) 6 to 8 months old, about 200-300 kg body weight, were allotted into 4
groups and kept in separate breeding stables where the animals were maintained
under veterinary care conditions and free access to regular concentrated ration
and water. These calves were previously screened for the presence of specific
antibodies against FMDV type SAT2 using VNT and did not reveal any specific
antibodies (seronegative). The four
groups are presented below:
Group (1): two calves were
used for virus titration.
Group (2): five calves were
vaccinated subcutaneously (S/C) with one field dose according to the
manufacture insert of the previously evaluated local commercial FMDV vaccine
batch (1).
Group (3): five calves were
vaccinated S/C) with one field dose according to the manufacture insert of the
previously evaluated local commercial FMDV vaccine batch (2).
Group (4): two calves were
kept as non-vaccinated group (control positive for challenge test).
Virus neutralization test
The test was performed in
BHK-21 cells by using the microtiter neutralization technique as described by
Ferriera(12) and
OIE.(11)
Virus titration in calves’ tongue
Infectivity titration of
FMDV strain SAT2 topotype VII, Lib-12 lineage (SAT2 Libya) to be used in the
challenge test, was carried out. Serial tenfold dilutions of the virus in
Hank's balanced salt solution were prepared for viral titration in the bovine tongue.
Dilutions were inoculated in the tongue of calves (two calves) whom were
hypnotized with a tranquilizer (Xylazine 20 mg/mL) with a dose of 0.2 mg/kg
body weight before virus inoculation. The tongue of calves was divided into
rows by using Indian ink; each dilution was inoculated intradermolingually in a
raw, at five sites, using 0.1 mL for each. The inoculated tongue sites were
examined carefully and the induced lesions were recorded daily during 3 days
post-inoculation to asses vesicles formation as reported by Dekker et al;(13)
to avoid rupture of these vesicles, a tranquilizer was applied to cattle before
tongue examination. The virus titer was calculated and expressed as Log10 Bovine
infective dose BID50/mL according to Karber.(14)
Challenge test
At 28th day post
vaccination, both vaccinated calves’ groups (2 and 3) and control group (4)
were moved to challenge room at animal house facility where were challenged
(after bleeding). The challenge virus serotype SAT2, topotype VII, Lib-12
lineage (SAT2 Libya) was adjusted to a titer of 104 BID50/0.3mL
and inoculated intradermolingual into 3 to 5 sites for each animal. The
challenged calves were observed daily for significant clinical signs (tongue
and feet ulcers) of FMDV during 7 days. Animals that showed clinical signs were
subjected to virus re-isolation. Positive control animals must show at least
three feet ulcers for the test to be considered the valid. The protection level
against generalized foot infection should be not less than 75% (at least 3.75
animals out of 5 vaccinated animals); the mean value for expectancy of
protection (EPP) of 75% indicates the vaccine strain is suitable to be used
together with appropriate field measures to control outbreaks with the field
strain under test.(11,15)
The animals that were used
for the challenge test were hypnotized before the challenge and at one time of
examination. The infected animals received veterinary care and medical
treatment until complete recovery and moved to a designated room for
ex-experimental animals.
The serological
relationship (r1-value) determination
At 28th day
post-vaccination, sera from animal immunized with vaccine batches 1 and 2
(groups 2 and 3) were collected (before the challenge) and tested against the vaccine
strain (SAT2/EGY/2/2012) and the field isolated strain (SAT2 topotype VII,
Lib-12 lineage) using VNT.(11,16) The serological relationships
(r1-value) were calculated according to the following equation:
Interpretation of r1-value:(11,17)
R < 0.3 indicated highly significant antigenic variation from the
vaccine strains and another vaccine strain should be chosen.
R > 0.3 demonstrated that the vaccine and field strains are
sufficiently similar and the vaccine could provide good protection.
Ethical
approval
Institutional Animal Care
and Use Committee at Central Laboratory for Evaluation of Veterinary Biologics
hereby acknowledges the research manuscript and it has been reviewed under our
research authority and is deemed compliance with bioethical standards in good
faith.
Results
Local commercial trivalent
oil inactivated FMDV vaccine batches (n=2) were produced in Egypt and prepared
from local isolate serotypes O/EGY/4/2012, A/EGY/1/2012, and SAT2/EGY/2/2012
which were previously evaluated at CLEVB for their potency against FMDV serotype
SAT2/EGY/2/2012 using VNT and challenge test. The FMDV vaccine batches
indicated satisfactory results as shown in Table 1.
Infectivity titration of
FMDV strain SAT2 topotype VII, Lib-12 lineage (SAT2 Libya) was assessed in
calves’ tongue (group 1). The titer was 106 BID50/mL.
Both vaccinated groups (2
and 3) with inactivated FMDV vaccine batches (1 and 2) and control calves group
(4 non-vaccinated) that were bled before the challenge for screening of
antibody titer at 28th day post-vaccination using VNT, showed
neutralizing antibody titers 0.48, 0.39 and 0.15 log10, respectively; regarding
the challenge test, the protection level indicated 20%, 0% and 0% against SAT2
Libya, respectively as shown in Table 1, in comparison to the results obtained
against FMDV serotype SAT2/EGY/2/2012.
Characteristic lesions in
tongue and feet were recorded at 7-day post challenge for vaccinated calve
groups (2 and 3) and control group (4); severe lesions in the four feet and
mild to moderate lesions at the tongue were shown for all recorded positive
animals (challenge test).
Table 1. Evaluation of humoral immune response and protection level of vaccinated
calves with inactivated FMDV vaccine batches using VNT and challenge test.
|
Vaccine batches No |
SAT2/EGY/2/2012 |
SAT2, topotype VII,
Lib-12 lineage (SAT2 Libya) |
|||
|
1 |
2 |
1 (Group 2) |
2 (Group 3) |
Positive control (Group 4) |
|
|
* VNT antibody titer (Log10 TCID50) |
2.46 |
2.1 |
0.48 |
0.39 |
0.15 |
|
** Protection level (Percentage %) |
100 |
100 |
20 |
0 |
0 |
*The protective virus neutralizing antibody
titer ≥ 1.65 log10
** The protection level (%) of challenge test
≥ 75%
The serological
relationship (r1-value) of the recently isolated FMDV type SAT2 topotype VII,
Lib-12 lineage (SAT2 Libya) was determined by VNT, using sera of vaccinated
calves (group 2 and group 3) with vaccine batches 1 and 2. The r1 values were
0.195 and 0.186, respectively as shown in Table 2.
Table 2. r1-value of FMDV type SAT2 topotype VII, Lib-12 lineage (SAT2
Libya) using VNT.
|
Vaccine Batches No. |
1 (Group 2) |
2 (Group 3) |
|
r1 value |
0.195 |
0.186 |
R < 0.3
indicated highly significant antigenic variation from the vaccine strains and
another vaccine strain should be chosen.
R > 0.3
demonstrated that the vaccine and field strains are sufficiently similar and
the vaccine would provide good protection.
Discussion
In
the 2018 FMDV outbreak, the Egyptian authorities declared the emergency and
triggered highly control and precautionary measures for tackling the outbreak.
Extensive surveillance promoted early isolation and identification of FMDV and
rapid response to combat the FMDV outbreak efficiently. The genomic sequencing
and variation analysis studies indicated the newly emerged FMDV was closely
related to strains isolated from Libya (topotype VII, lineage3) and clearly
differed from endemic strains SAT2/GVII/Gharbia/Egy/2012 and
SAT2/GVII/Alex/Egy/2012 (topotype VII, lineage 2).(8,9)
The
control of FMDV disease mainly depends on the availability of effective
vaccines that can be selected based on genome alignment, epidemiological
information, and serological cross-reactivity of bovine post-vaccinal serum
with circulating viruses. In addition, the availability of sufficient doses of
vaccines of good quality and potency is also equally considered.(18,19,20)
Polyvalent inactivated vaccines are currently used in Egypt for FMDV
prevention, but the recent circulating field isolates
indicated genomic variation in relation to the vaccinal strain (SAT2),(8,9)
a likelihood of impotence of existing vaccines;
therefore we investigate the efficacy of the available local commercial vaccine
against the recently isolated strain FMDV strain SAT2 topotype VII, Lib-12
lineage (SAT2 Libya) using VNT and challenge test.
The
local commercial trivalent oil inactivated FMDV vaccine batches (n=2) were
produced in Egypt, prepared from local isolate serotypes O/EGY/4/2012,
A/EGY/1/2012 and SAT2/EGY/2/2012 and previously evaluated with satisfactory results.
The FMDV vaccine batches were inoculated (S/C) in calves from groups 2 and 3.
In calves immunized with these two vaccine batches, the humoral immune response
against the FMDV field strain SAT2, topotype VII, Lib-12 lineage, was
determined by VNT and exhibited titers of 0.48 and 0.39 log10, respectively;
while the humoral immune response against the FMDV vaccinal strain
SAT2/EGY/2/2012 using VNT indicated 2.46 and 2.1 log10, respectively, regarding
the minimum protective virus-neutralizing antibody titer (1/45) 1.65 log10.(11) In a similar study it was found that the
immunogenicity of SAT2 strain in cattle recorded high and uniform neutralizing
antibodies levels after 2 weeks of vaccination ≥ 1:45.(21) The
serological relationship (r1-value) of the recently isolated FMDV type SAT2
topotype VII, Lib-12 lineage (SAT2 Libya) was assessed and calculated, the
r1-values were 0.195 and 0.186 for vaccine batches 1 and 2, respectively.
According to OIE,(11) for neutralization, r1-values
greater than 0.3 indicate a close antigenic relationship between the vaccine
strain and the field isolate, a likelihood that the vaccine strain confers
cross-protection against the field strain; whereas r1-values less
than 0.3 indicate a lack of such cross-protection. Interestingly, similar
studies demonstrated that a system for FMDV strain differentiation based on the
use of the virus neutralization reaction is recomended, taking into account the
statistical and biological significance of observed r values.(22,23) Another recent study compared the antigenic relationship (r1 values) of
the outbreak viruses with reference antisera and indicated a good vaccine match
with 90% of r1 values > 0.3. The r1 values for the 2013/2014 outbreak
viruses were 0.4 and above for the three South African vaccine/reference
strains. These results confirmed the presence of genetic and antigenic
variability in SAT2 viruses and suggest the emergence of new variants at the
wildlife–livestock interface in South Africa.(24)
The
results for protection level of vaccine batches (1 and 2) against FMDV strain
SAT2 topotype VII, Lib-12 lineage indicated 20% and 0%, respectively, compared
to challenge test results against FMDV SAT2/EGY/2/2012, which indicated 100% for
both batches. The OIE(11)
recommended a 75% cut off of vaccine potency acceptance for vaccines intended
for use in regular vaccination regimens, and the expectancy protection method
using a 75% cut off for fitness of a vaccine to be used against field isolates,
which has been used with great success in South America to control outbreaks.(25)
Previous
studies(8,9) indicated the clear genetic variation between the FMDV
SAT2 Libya (topotype VII, lineage 3) and the endemic strains
SAT2/GVII/Gharbia/Egy/2012 and SAT2/GVII/Alex/Egy/2012 (topotype VII, lineage
2), which is consistent with the relevant results of the current study that
demonstrated the insufficient antigenic relationship of the current circulating
VFA SAT2 topotype VII, lineage Lib-12 with the VFA vaccine strain
SAT2/EGY/2/2012, and that existing vaccines against FMDV cannot induce cross-protection
against circulating field isolation neither in in vitro nor in vivo
studies.
Conclusions
The
available local commercial inactivated FMDV vaccine batches (SAT2 SAT2/EGY/2/2012) are impotent and not effective against the current circulating FMDV filed isolate SAT2
topotype VII, Lib-12 lineage; it is highly recommended to update the existing
vaccines with the isolated strain.
References
1. Knight-Jones TJD,
Rushton J. The economic impacts of foot
and mouth disease-what are they, how big are they and where do they occur? Prev
Vet Med. 2013;112(3-4):162–73.
2. Grubman MJ, Baxt B. Foot-and-mouth disease. Clin Microbiol Rev.
2004; 17 (2): 465-93.
3.
Alexandersen S,
Zhang Z, Donaldson AI, Garland AJ. The
pathogenesis and diagnosis of foot-and-mouth disease. J Comp Pathol.
2003;129(1):1-36.
4. Arzt J, Juleff N, Zhang
Z, Rodríguez LL. The Pathogenesis of
Foot‐and‐Mouth Disease I: Viral Pathways in Cattle. Transbound Emerg Dis.
2011;58: 291-304.
5. Knowles NJ, Wadsworth J,
Reid SM, Swabey KG, El-Kholy AA, El-Rahmanet AOA, et al. Foot-and-mouth disease virus serotype A in Egypt. Emerg Infect Dis.
2007;13(10):1593-6.
6. Sobhy NM, Mor SK,
Mohammed MEM, Bastawecy IM, Fakhry HM, Youssef CRB, et al. Phylogenetic analysis of Egyptian foot and
mouth disease virus endemic strains. J Am Sci. 2014:10:133–8.
7. Valdazo-González B,
Knowles NJ, Hammond J, King DP. Genome
sequences of SAT 2 foot-and-mouth disease viruses from Egypt and Palestinian
Autonomous Territories (Gaza Strip). J Virol. 2012;86(16):8901-2.
8. Soltan MA, Dohreig RMA,
Abbas H, Ellawa M, Yousif I, Aly AE, et al. Emergence of Foot and mouth disease virus, Lib 12 lineage of topotype
VII, serotype SAT2 in Egypt, 2018. Transbound Emerg Dis. 2019; 66:1105–6. doi: https://10.1111/tbed.13152.
9. Hagag NM, Hamdy ME,
Sargious MA, Elnomrosy SM, Ahmed NA, Hamed AA, et al. Molecular and genetic characterization
of newly circulating foot and mouth disease virus (FMDV) serotype SAT2 in Egypt
during 2018 and early 2019. Hosts and Viruses.2020; 6(5): 103-8.doi: https://10.17582/journal.hv/2019/6.5.103.108.
10. Abousenna MS, Khafagy
HA, Abotaleb MM, Darwish DM, Barghooth WM, Shafik NG. Alternative method for
the evaluation of monovalent inactivated foot and mouth disease virus vaccine.
VacciMonitor. 2021: 30(1):4-9. Available at: https://vaccimonitor.finlay.edu.cu/index.php/vaccimonitor/article/view/244.
11. OIE. Organization for
Animal Health. Foot and Mouth Disease (infection with foot and mouth disease).
In: OIE. World Organization for Animal Health. Manual of diagnostic tests and
vaccines for terrestrial animals (mammals, birds, bees). Paris: OIE; 2021. p.
1-31. Available at: https://www.oie.int/.
12. Ferreira ME. Microtiter neutralization test for the study
of foot-and-mouth disease antibodies. Boletin Centro Pan Americano de Fiebre
Aftosa. 1976; 21(22): 17-20.
13. Dekker A, van Hemert-Kluitenberg
F, Oosterbaan AH, Moonen K, Mouton L. Replacement
of foot-and-mouth disease virus cattle tongue titration by in vitro titration.
ALTEX. 2018;35(4):489-94. doi: https://10.14573/altex.1712222.
14. Kärber G.Contribution to the collective treatment of
pharmacological series experiments. Arch Exp Pathol Pharmacol. 1931; 162:
480-3.
15. Nermeen SG, Darwish DM,
Abousenna MS, Galal M, Ahmed AR, Attya M, et al. Efficacy of a commercial local trivalent Foot and Mouth Disease (FMD)
vaccine against recently isolated O-EA3. Inter J Vet Sci.2019;8(1): 35-8. Available from:
https://www.ijvets.com/pdf-files/volume-8-no-1-2019/35-38pdf.
16. Kitching RP, Rendle R,
Ferris NP. Rapid correlation between
field isolates and vaccine strains of foot-and-mouth disease virus. Vaccine.1988;6(5):403-8.
17. Maree F, Kasanga C,
Scott K, Opperman P, Chitray M, Sangula A, et al. Challenges and prospects for the control of foot-and-mouth disease: an
African perspective. Vet Med (Auckl). 2014;5:119-38.
18. Balinda SN, Sangula AK,
Heller R, Muwanika VB, Belsham GJ, Masembe C, et al. Diversity and transboundary mobility of serotype O foot-and-mouth
disease virus in East Africa: implications for vaccination policies. Infect
Genet Evol. 2010;10(7):1058-65.
19. Wekesa SN, Muwanika VB,
Siegismund HR, Sangula AK, Namatovu A, Dhikusooka MT, et al. Analysis of Recent Serotype O Foot-and-Mouth
Disease Viruses from Livestock in Kenya: Evidence of Four Independently
Evolving Lineages. Transbound Emerg Dis. 2015;62(3):305-14.
https://doi.org/10.1111/tbed.12152.
20. Kerfua SD, Shirima G,
Kusiluka L, Ayebazibwe C, Martin E, Arinaitwe E, et al. Low topotype diversity of recent
foot-and-mouth disease virus serotypes O and A from districts located along the
Uganda and Tanzania border. J Vet Sci. 2019;20(2):e4. https://doi.org/10.4142/jvs.2019.20.e4
21. Jo HE,
You SH, Choi JH, Ko MK, Shin SH, Song J, et
al. Evaluation of novel inactivated vaccines for the SAT 1, SAT 2
and SAT 3 serotypes of foot-and-mouth disease in pigs. Virol J. 2019;16(1):156. doi:https://10.1186/s12985-019-1262-1.
22. Rweyemamu MM. Antigenic variation in foot-and-mouth disease:
studies based on the virus neutralization reaction. J Biol
Stand.1984;12(3):323–37.
23.Willems T, De
Vleeschauwer A, Perez-Filgueira M, Li Y, Ludi A, Lefebvre D, et al. FMD vaccine matching: Inter laboratory study for improved understanding
of r1 values. J Virol Methods.2020;276:113786. doi:
https:/10.1016/j.jviromet.2019.113786.
24. Blignaut B, van Heerden
J, Reininghaus B, Fosgate GT, Heath L.
Characterization of SAT2 foot‐and‐mouth disease 2013/2014 outbreak viruses at
the wildlife–livestock interface in South Africa. Transbound Emerg Dis. 2020;
67(4): 1595–1606. doi:https://10.1111/tbed.13493.
25. Leon EA,
Perez AM, Stevenson MA, Robolio B, Mattion NM, Seki C, et al. Effectiveness of systematic foot and mouth
disease mass vaccination campaigns in Argentina. Rev Sci Tech.
2014;33(3):917–26.
Conflict of interest
The author certifies that
he has no affiliations with or involvement in any organization or entity with
any financial interest (such as honoraria; educational grants; participation in
speakers’ bureaus; membership, employment, consultancies, stock ownership, or
other equity interest; and expert testimony or
patent-licensing arrangements), or non-financial interest (such as
personal or professional relationships, affiliations, knowledge or beliefs) in
the subject matter or materials discussed in this manuscript.
*Assistant Professor, PhD of
Virology, Central Laboratory for Evaluation of Veterinary Biologics, Cairo,
Egypt.