Epidemiological Characteristics and Phylogenetic Analysis of Lumpy Skin Disease in Cattle in the Mekong Delta of Vietnam
Research Article
Epidemiological Characteristics and Phylogenetic Analysis of Lumpy Skin Disease in Cattle in the Mekong Delta of Vietnam
Tran Ngoc Bich1*, Vo Tuan Khai Huyen2, Nguyen Tran Phuoc Chien1, Dang Thi Tham1, Nguyen Vinh Trung1, Truong Van Hieu3, Thai Quoc Hieu4, Huynh Truong Giang1, Le Quang Trung1
1Faculty of Veterinary Medicine, College of Agriculture, Can Tho University, Can Tho, Vietnam; 2Interdisciplinary Graduate Program in Animal pathology and disease treatment, Faculty of Veterinary Medicine, College of Agriculture, Can Tho University, Can Tho, Vietnam; 3Department of Animal Science and Veterinary Medicine, School of Agriculture and Aquaculture, Tra Vinh University, Tra Vinh, Vietnam; 4Tien Giang Sub-Department of Animal Health, Ministry of Agriculture and Rural Development, Tien Giang, Vietnam.
Abstract | Lumpy skin disease (LSD) is an increasing threat to the global cattle industry, and Vietnam is among the countries recently affected. In response to this growing concern, a cross-sectional study was conducted to assess the infection status and risk factors associated with LSD outbreaks in the Mekong Delta. The study documented an LSD outbreak in the Mekong Delta provinces of Tien Giang, Tra Vinh, and Ben Tre between May 2023 and June 2024. A questionnaire-based survey was conducted through face-to-face interviews with farmers impacted by the disease. The collected epidemiological data were analysed, and the LSDV strains were genetically characterised. Out of 1,278 animals clinically examined across 180 farms, 80 tested positive via PCR, resulting in a morbidity rate of 6.26% and a herd prevalence of 37.22%. The morbidity rates in the 19 districts surveyed ranged from 1.45% to 17.95%. Risk factor analysis revealed that unvaccinated animals had the highest incidence rate at 17.94% (P<0.05), with an OR of 5.52 (95%CI: 3.62–8.44). Additionally, calves under six months old have a significantly higher risk of LSD compared to cows aged 6–24 months (OR 1.84, 95%CI: 1.14–3.00) and compared to animals older than 24 months (OR 4.82, 95% CI: 2.73-8.51). Phylogenetic analysis of the P32 gene of LSDV (PP934191-PP934205) indicated 100% similarity with other isolates from China, Russia, and Thailand. The findings of this study provide critical epidemiological insights into the risk factors associated with LSD in the Mekong Delta. This information is essential for government livestock regulators to develop effective prevention and control strategies, thereby mitigating the negative impact of LSD on cattle farming.
Keywords | Lumpy skin disease virus, Epidemiological, Characterization, Gene P32, Mekong Delta, Vietnam
Received | July 15, 2024; Accepted | August 20, 2024; Published | October 10, 2024
*Correspondence | Tran Ngoc Bich, Faculty of Veterinary Medicine, College of Agriculture, Can Tho University, Can Tho, Vietnam; Email: tnbich@ctu.edu.vn
Citation | Tran Ngoc Bich, Vo Tuan Khai Huyen, Nguyen Tran Phuoc Chien, Dang Thi Tham, Nguyen Vinh Trung, Truong Van Hieu, Thai Quoc Hieu, Huynh Truong Giang, Le Quang Trung. Adv. Anim. Vet. Sci. 12(11): 2284-2292.
DOI | https://dx.doi.org/10.17582/journal.aavs/2024/12.11.2284.2292
ISSN (Online) | 2307-8316; ISSN (Print) | 2309-3331
Copyright: 2024 by the authors. Licensee ResearchersLinks Ltd, England, UK.
This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (https://creativecommons.org/licenses/by/4.0/).
INTRODUCTION
The World Organisation for Animal Health (OIE) categorises Lumpy Skin Disease (LSD) as a transboundary disease because of its rapid dissemination and substantial economic consequences (Tuppurainen and Oura, 2012). First identified in Zambia in 1929, the Neethling strain of Capripoxvirus causes LSD. The disease is widespread throughout Africa and the Middle East. The recombinant lineages of LSDV, which originated from the Middle East and Africa, have disseminated throughout China, Mongolia, Vietnam, Cambodia, Laos, Thailand, Malaysia, and Indonesia (Li et al., 2023). The first instance of LSD use in Vietnam was documented in Lang Son province around October 2020. Since then, LSD has been reported in 55/63 provinces and cities, 457 districts, and 4,280 communes. From January to May 2024, 68 outbreaks were reported in 10 provinces, with 404 diseased cattle and 93 buffaloes and cows destroyed, marking a 9.67% increase compared to 2023 (DAH, 2024). LSD causes circular, slightly elevated papules on the neck, legs, tail, and back after the onset of fever (Şevik and Doğan, 2017). The disease can reduce milk production by 10% to 85% due to high body temperature and secondary mastitis, and it may cause lasting skin damage, impaired cattle development, infertility, miscarriage, and death (Şevik et al., 2016). Viral genomes are identified in nodules, ulcers, secretions, semen, and infected cattle blood (Bedeković et al., 2018). PCR targeting the P32 gene is commonly used for LSDV identification and analysis (Sameea Yousefi et al., 2018). The P32 protein is highly conserved across Capripoxviruses, enabling differentiation between SPPV (Sheep pox virus), GTPV (Goat pox virus), and LSDV (Koirala et al., 2022). The preservation of the P32 protein renders it a dependable indicator for genetic investigations on Capripoxviruses. There are currently no studies or publications on the LSD situation in the Mekong Delta; this study was done to investigate the prevalence of LSD in the Mekong Delta, Vietnam, in light of the rising number of LSDV cases reported to the Department of Animal Health Vietnam till May 2024. The inquiry included contemporaneous surveillance of the sickness and examination of historical data. Our objective was to assess the effectiveness of the PCR technique, which mainly focuses on the P32 gene for identification, and to characterise LSDV isolates using molecular methods.
MATERIALS AND METHODS
Specimen Collection
The LSD epidemic was investigated in 180 houses in Tien Giang, Ben Tre, and Tra Vinh in Vietnam’s Mekong Delta from May 2023 to June 2024. In the Mekong Delta, known for its large cow population (Figure 1, Figure 2), farmer complaints and proactive case identification by LSD led to investigations. Veterinary inspections and farmer reports on afflicted cattle ranches identified outbreaks as farms with at least one LSD case. LSD cases were identified by clinical symptoms such as raised, spherical, and solid nodules measuring 2-7 cm in diameter (Şevik and Doğan, 2017). The study included 1,278 bovines assessed for LSD symptoms. Nasal swab samples were collected aseptically, preserved on ice, and sent to the Faculty of Veterinary Medicine at Can Tho University. Samples were stored at -20°C until processing, following TCCS 04:2020/TY–DT (MARD, 2020) and (OIE, 2017) guidelines.
DNA Extraction and PCR Detection of Virus
Viral DNA was isolated from nasal swab samples using a TopPURE® RNA/DNA Viral Extraction Kit (ABT, Vietnam). LSDV presence was confirmed with a PCR assay targeting the P32 gene, using the primers forward 5′-TTTCCTGATTTTTCTTACTAT-3′ and reverse 5′-AAATTATATACGTAAATAAC-3′, producing a 192 bp amplicon (OIE, 2017). The PCR was performed in a 25 μL reaction mixture with 12 μL GoTaq® DNA Polymerase (Promega, USA), one μL of each ten μM primer, eight μL deionised water, and three μL DNA template. Cycling conditions were: 5 minutes at 94°C, 35 cycles at 94°C for 60 seconds, 50°C for 30 seconds, and 72°C for 60 seconds, with a final 5 minutes at 72°C. PCR products were analysed by electrophoresis on a 1.5% agarose gel stained with ethidium bromide and visualised using a BIO-Rad UV transilluminator.
Fifteen representative samples from Tien Giang, Ben Tre, and Tra Vinh in Vietnam’s Mekong Delta were selected for PCR assay targeting the P32 gene for phylogenetic analysis, using the primers P32-F (5′-TCGTTGGTCGCGAAATTTCAG-3′) and P32-R (5′-GAGCCATCCATTTTCCAACTCT-3′). This produced a 759 bp fragment between nucleotides 65163-65921 (Sameea Yousefi et al., 2018). The PCR reaction was prepared similarly, with cycling conditions of 5 minutes at 94°C, 35 cycles of 95°C for 45 seconds, 56°C for 45 seconds, and 72°C for 65 seconds, followed by a final 5 minutes at 72°C. PCR products were visualised on a 1.5% agarose gel.
Nucleotide Sequencing and Phylogenetic Analysis
The P32 amplicons, which were 759 bp in length, were purified from the PCR products using the TopPURE® PCR/Gel DNA purification kit from ABT, Vietnam. The purified products were sequenced on both forward and reverse strands by NamKhoa-Biotech, Vietnam. Sanger sequencing was executed using the ABI Prism BigDye™ Terminator v1.1 cycle sequencing kit on an ABI PRISM 3500 × l Genetic Analyzer.
The LSDV P32 sequences were aligned multiple times using Geneious Prime® version 2024.0.2, with manual corrections. The NCBI BLAST tool assessed the sequences’ similarity to GenBank sequences (https://www.ncbi.nlm.nih.gov/). The objective was to determine the taxonomic categorisation of the sequences within the CaPV genus. Nucleotide sequences were aligned and compared with P32 gene sequences of other LSDV, SPPV, and GPV viruses from GenBank using Clustal W. A phylogenetic tree was constructed using the maximum-likelihood technique with the Tamura-Nei model in MEGA v.11.0 software. The reliability of the tree’s branching patterns was evaluated by bootstrap analysis with 1000 replications. The trees were created and labelled using the Interactive Tree of Life (iTOL) program (https://itol.embl.de). They were analysing nucleotide similarity ratios using STD v.1.3 software. The nucleotide sequences of the P32 gene for all 15 LSDV isolates were uploaded to the GenBank database and assigned accession numbers PP934191-PP934205.
Data Analysis
Every shepherd participated in a survey aimed at analysing risk factors for LSD, with epidemiological data analysed using Microsoft Excel 2010. Descriptive analysis was conducted to assess the frequency, central tendency, and dispersion of quantitative variables and the percentage of qualitative variables. Predictor factors included gender, age (< 6 months, 6-24 months, > 24 months), breed (crossbreeds or native breeds), grazing pattern (communal or zero-grazing), and vaccination status. The response variable was PCR-detected LSD. A generalised linear model was employed to compare epidemiological factors by breed, sex, vaccination status, and age. Model coefficients were converted to odds ratios (ORs) using exponential transformation, with statistical significance set at 0.05. Favourable rates were analysed using Chi-square and Fisher’s exact tests (P < 0.05) via WinEpi (http://www.winepi.net). Direct odds ratios were estimated using the Mantel-Haenszel technique, providing a precise 95% binomial confidence interval.
RESULTS AND DISCUSSION
Infection Situation and Risk Factors for LSD Infection in the Study
The research utilised PCR to screen 1,278 cattle from 180 households for LSDV, identifying 80 positive cases and determining a morbidity rate of 6.26%. The epidemic’s impact varied across the 19 districts, with morbidity rates ranging from 1.45% to 17.95% (Table 1, Figure 3). Notably, the outbreak did not result in any fatalities. Results show that the highest infection rate was in Ben Tre at 6.27%, varying between 2.27% and 14.9% across different districts. Tien Giang followed this at 6.04% and Tra Vinh at 5.82%, with no significant difference between the provinces (P>0.05). Differences in disease incidence compared to previous studies may be attributed to geographic factors, farm practices, insect activity, circulating LSDV strains, and variations in animal populations and immune status (Tuppurainen and Oura, 2012; Bianchini et al., 2023; Tran et al., 2024).
The severity of LSD symptoms in cattle varied. Common clinical signs included depression, decreased appetite, elevated body temperature, and discharge from the nose and eyes. Additionally, swollen lymph nodes and localised skin nodules measuring 2–7 cm were observed in various body areas. These nodules sometimes spread throughout the body (Figure 4). This observation is consistent with findings by Li et al. (2023), which reported that severe LSD can cause significant nodules, leading to discomfort and stiffness. Necrotic nodules, prone to secondary bacterial infections, underscore the need for vigilant monitoring and treatment (El-Neweshy et al., 2013). The study offers valuable insights into LSD outbreaks in small backyard cattle, with clinical signs aligning with previous reports (Şevik and Doğan, 2017; Wolff et al., 2021). Notably, the sloughing
Table 1: Epidemiological characteristics of LSD outbreaks in cattle.
Province |
Study area |
Farms |
Animals |
||||
No. |
positive |
Morbidity rate (%) |
No. |
positive |
Morbidity rate (%) |
||
Tien Giang |
My Tho city |
10 |
4 |
40.00 |
65 |
6 |
9.23 |
Cho Gao district |
10 |
4 |
40.00 |
117 |
6 |
5.13 |
|
Chau Thanh district |
10 |
1 |
10.00 |
69 |
1 |
1.45 |
|
Go Cong town |
7 |
4 |
57.14 |
39 |
7 |
17.95 |
|
Go Cong Tay district |
8 |
2 |
25.00 |
26 |
3 |
11.54 |
|
Go Cong Dong district |
6 |
1 |
16.67 |
33 |
1 |
3.03 |
|
Tan Phu Dong district |
9 |
1 |
11.11 |
65 |
1 |
1.54 |
|
Ben Tre |
Ba Tri district |
9 |
6 |
66.67 |
67 |
10 |
14.93 |
Giong Trom district |
11 |
3 |
27.27 |
132 |
3 |
2.27 |
|
Thanh Phu district |
11 |
2 |
18.18 |
67 |
2 |
2.99 |
|
Mo Cay Nam district |
11 |
9 |
81.82 |
118 |
9 |
7.63 |
|
Mo Cay Bac district |
11 |
8 |
72.73 |
77 |
8 |
10.39 |
|
Chau Thanh district |
7 |
1 |
14.29 |
25 |
1 |
4.00 |
|
Tra Vinh |
Cang Long district |
10 |
3 |
30.00 |
57 |
3 |
5.26 |
Chau Thanh district |
10 |
4 |
40.00 |
65 |
5 |
7.69 |
|
Tieu Can district |
10 |
2 |
20.00 |
60 |
2 |
3.33 |
|
Cau Ngang district |
10 |
2 |
20.00 |
70 |
2 |
2.86 |
|
Tra Cu district |
10 |
4 |
40.00 |
59 |
4 |
6.78 |
|
Cau Ke district |
10 |
6 |
60.00 |
67 |
6 |
8.96 |
|
Total |
180 |
67 |
37.22 |
1,278 |
80 |
6.26 |
of lesions resulted in a “reverse cone” appearance, facilitating worm infestation and bacterial invasion, potentially worsening sepsis.
The analysis results (Table 2) revealed that factors such as province, sex, breed, and age did not show a statistically significant relationship with the incidence of LSD.
However, the study found that both the animal’s age and its vaccination status had significant associations with LSD status. Specifically, the incidence of LSD was significantly higher in non-vaccinated animals compared to those that had been vaccinated, with an OR of 5.52 (95%CI: 3.62–8.44; P<0.05). This indicates that animals without vaccination were much more likely to develop LSD. Although there is a clear difference in disease incidence between vaccinated (3.25%) and unvaccinated cattle (17.52%), the infection rate among vaccinated cattle is still higher than expected. Several factors may explain this: vaccination coverage is suboptimal due to some cattle being too young for the LSD vaccine and delays in administering booster doses. Tuppurainen et al. (2021), emphasise that cattle aged six
Table 2: Summary of associated risk factors related to lumpy skin disease in cattle.
Variables |
Category |
The number of examined animals |
Number of clinically affected animals |
Morbidity rate (%) |
OR |
95%CI |
P-value |
Province |
Ben Tre |
486 |
33 |
6.79 |
Ref. |
||
Tien Giang |
414 |
25 |
6.04 |
1.12 |
0.68-1.86 |
0.647 |
|
Tra Vinh |
378 |
22 |
5.82 |
1.17 |
0.69-1.97 |
0.562 |
|
Sex |
Male |
619 |
39 |
6.30 |
Ref. |
||
Female |
659 |
41 |
6.22 |
1.01 |
0.66-1.55 |
0.954 |
|
Breed |
Crossbreeds |
829 |
55 |
6.63 |
Ref. |
||
Native breeds |
449 |
25 |
5.57 |
1.19 |
0.75-1.88 |
0.452 |
|
Grazing |
Communal |
149 |
12 |
8.05 |
Ref. |
||
Zero-grazing |
1,129 |
68 |
6.02 |
1.34 |
0.74-2.41 |
0.336 |
|
Vaccine |
No |
262 |
47 |
17.94 |
Ref. |
||
Yes |
1,016 |
33 |
3.25 |
5.52 |
3.62-8.44 |
0.000 |
|
Age |
<6 months |
164 |
24 |
14.63 |
Ref. |
||
6-24 months |
455 |
36 |
7.91 |
1.84 |
1.14-3.00 |
0.013 |
|
>24 months |
659 |
20 |
3.03 |
4.82 |
2.73-8.51 |
0.000 |
CI: confidence interval; OR: odds ratio; Ref: reference.
months and older need vaccination for disease prevention. Kumar et al. (2023), note that poor hygiene during immunisation can lead to virus transmission through needles. Additionally, improper vaccine storage or insufficient time for protective antibody development can reduce vaccine efficacy. LSD in vaccinated animals may result from inadequate vaccination protocols, ineffective vaccines, or infection before immunity develops (Kasem et al., 2018). These factors underscore the need for effective vaccination strategies and ongoing monitoring to manage LSD outbreaks.
Furthermore, age also played a crucial role in the likelihood of contracting LSD. Calves under six months old were at a significantly higher risk than cows aged 6–24 months, with an OR of 1.84 (95% CI: 1.14–3.00; P<0.05). Additionally, the incidence of LSD was markedly greater in calves under six months old compared to animals older than 24 months, with an OR of 4.82 (95% CI: 2.73-8.51; P<0.05). The high disease incidence in cattle under six months of age can be explained by their underdeveloped immune system and the lack of protective immunity from vaccines or their mothers. During the survey, many mother cows were not fully vaccinated or had little time to develop an effective immune response. Furthermore, research by Leliso et al. (2021) in Ethiopia, Bianchini et al. (2023), Faris et al. (2021) in Egypt, and Tran et al. (2024) also indicate that younger and weaker cattle are at a higher risk of disease than mature and healthy cattle. These findings underscore the importance of vaccination as a preventive measure against LSD and highlight the increased vulnerability of younger animals, particularly those under six months old, to the disease.
Phylogenetic Analysis and Estimated Identity Between P32 Gene Sequences of CaPVs
The Capripoxvirus (CaPVs) genus includes closely related viruses that infect domestic ruminants, such as cattle, sheep, and goats, and cause significant economic losses in livestock production. This study utilised nucleotide sequences of the P32 gene, an essential immunogenic protein in all Capripoxvirus species phylogenetic analysis, to explore genetic diversity within the genus. A phylogenetic tree was constructed using the P32 gene’s nucleotide sequences (759 bp) from various CaPVs, revealing distinct and unique clusters for LSDV, SPPV, and GTPV, highlighting genotypic diversity despite genomic similarities.
Sequencing of 15 LSD viruses from cattle in the Tien Giang, Ben Tre, and Tra Vinh provinces in the Mekong Delta of Vietnam showed close clustering with LSDV strains from other regions globally. The phylogenetic tree grouped LSDVs into two subclusters: sub-cluster I-a included strains from Kenya, Serbia, Egypt, Saudi Arabia, Kazakhstan, Kurdistan, and South Africa, while sub-cluster I-b encompassed strains from North Vietnam, China, Thailand, Hong Kong, Taiwan, Indonesia, Russia, and LSDV vaccine strains. The LSDVs from this study are closely aligned with sub-cluster I-b (Figure 5). The P32 gene’s high conservation makes it a valuable tool for molecular diagnosis and genetic characterisation of CaPVs, enabling differentiation between virus members (Sprygin et al., 2018). The study confirmed that LSDV sequences from the Mekong Delta were highly similar to those from North Vietnam, China, Russia, and Thailand, with 100% nucleotide sequence identity. This finding supports prior research
on the adequate amplification and sequencing of the P32 gene (Trinh et al., 2022).
The analysis revealed a clear distinction between LSDV field strains affecting cattle and those causing disease in sheep and goats. LSDV strains from the Mekong Delta were found to be closely related to Neethling vaccine strains, such as SIS/Lumpyvac, Neethling/Herbivac, and Neethling/OBP, indicating that the circulating virus is of the Neethling strain. This supports the effectiveness of vaccines in controlling LSD. However, recent outbreaks of recombinant strains similar to vaccines have been reported in Russia, Kazakhstan, China, and Vietnam (Sprygin et al., 2018; Issimov et al., 2022; Wang et al., 2022; Tran et al., 2021), highlighting the need for ongoing surveillance to detect and identify new recombinant virus strains promptly.
Estimates of Sequence Identity Between Capripoxvirus P32 Gene Sequences
The calculated sequence identity across P32 sequences of CaPVs showed a nucleotide similarity ranging from 97.3% to 100% among these viruses. In this study, the nucleotide sequences of the P32 gene from the LSDV isolates and two other viruses, SPPV and GTPV, showed a 97.3–98.0% similarity. The P32 nucleotide similarity percentage between LSDVs from the Mekong Delta in Vietnam and those from other countries ranged from 99.1% to 100%. The P32 antigen sequences of the LSDV strains studied in the Mekong Delta of Vietnam, with accession numbers PP934191-PP934205, exhibit 100% similarity. These sequences are also 100% identical to the Neethling strain of the LSDV vaccine (accession numbers AF409138, KX764643, KX764644, and KX764645), as well as to strains from North Vietnam (LC648887, MW326768, LC663765), China (MW355944, MN598005, OM046584), Thailand (OM033705), Hong Kong (MW732649), Taiwan (MZ934387), Indonesia (OR232413), and Russia (OM793603). The nucleotide sequence similarity was lower, at 99.2%, compared to strains India (MW452623), Kurdistan (KM047055), Kenya (MN072619), and Kazakhstan (MN642592) identified in countries of South Asia, West Asia, and Africa (Figure 6).
Since its initial discovery in 1929 in Zambia, Capripoxvirus has spread extensively across Africa and the Middle East. Over time, the virus’s movement across continents in its hosts has led to changes in nucleotide sequences. Despite these changes, they are relatively minor. According to Tulman et al. (2001) and Rashid et al. (2017), this stability is attributed to the Poxviridae family’s large and complex genome, which consists of a single, linear double-stranded DNA (dsDNA) molecule encoding approximately 200 proteins. The continuous nature of the DNA molecule, with no free ends, results in a low mutation rate. As a result, the genetic differences observed in the P32 genes between strains studied in Vietnam and the original African strains are minimal. This indicates the virus’s genetic stability and highlights the importance of ongoing monitoring and research to understand the virus’s evolution and spread better.
CONCLUSIONS AND RECOMMENDATIONS
Additional investigation is required to study the widespread dissemination of LSD throughout a vast geographical area. In the Mekong Delta of Vietnam, the prevalence of LSD has primarily impacted calves less than six months old, with a major contributing factor being the absence of immunisation. The incidence of LSD among individual animals is 6.26%, whereas the occurrence of LSD among herds is 37.22%. The PCR test focusing on the P32 gene is a fast and reliable technique for identifying LSDV field isolates. Utilising the nucleotide sequence of the P32 gene for phylogenetic research might provide practical assistance in identifying the source and management of LSD.
ACKNOWLEDGEMENTS
The authors thank the technical staff of Tien Giang Sub-Department of Animal Health, Ben Tre Sub-Department of Animal Health, Tra Vinh Sub-Department of Animal Health and students from the Faculty of Veterinary Medicine, College of Agriculture, Can Tho University, who helped with the sample collection and analysis. We would also like to acknowledge the cattle farmers of the area for their valuable cooperation.
AUTHORS’ CONTRIBUTIONS
This research was conducted with the contributions of all the authors. The authors all participated in the study design, analysing the results, interpreting the results, and preparing the manuscript. All authors read and approved the final manuscript.
Ethics Statement
This study was carried out on naturally infected animals. The samples used for this study were diagnostic, and no experimental procedures were carried out in any animal. Written informed consent was obtained from the owners for the participation of their animals in this study.
Funding
This research is supported by the Vietnam Ministry-Level Scientific Project under Project Code No. B2023-TCT-13.
Conflict of Interest
We certify that there is no conflict of interest.
REFERENCES
Bianchini J, Simons X, Humblet MF, Saegerman C (2023). Lumpy skin disease: a systematic review of mode of transmission risk of emergence and risk entry pathway. Viruses 15(8): 1622. https://doi.org/10.3390/v15081622
Bedeković T, Šimić I, Krešić N, Lojkić I (2018). Detection of lumpy skin disease virus in skin lesions blood nasal swabs and milk following preventive vaccination. Transboundary Emerg. Dis., 65(2): 491-496. https://doi.org/10.1111/tbed.12730
DAH (Department of Animal Health) (2024). Report on the epidemic situation of papular dermatitis November 6 2024. Ha Noi Vietnam.
El-Neweshy MS, El-Shemey TM, Youssef SA (2013). Pathologic and immunohistochemical findings of natural lumpy skin disease in Egyptian cattle. Pak. Vet. J., 33(1): 60-64. https://www.researchgate.net/profile/Tharwat-Elshemey/publication/327079311
Faris DN, El-Bayoumi K, El-Tarabany M, Kamel ER (2021). Prevalence and risk factors for lumpy skin disease in cattle and buffalo under subtropical environmental conditions. Adv. Anim. Vet. Sci., 9(9): 1311-1316. http://dx.doi.org/10.17582/journal.aavs/2021/9.9.1311.1316
Issimov A, Kushaliyev K, Abekeshev N, Molla W, Rametov N, Bayantassova S, Zhanabayev A, Paritova A, Shalmenov M, Ussenbayev A, Kemeshov Z (2022). Risk factors associated with lumpy skin disease in cattle in West Kazakhstan. Prev. Vet. Med., 207: 105660. https://doi.org/10.1016/j.prevetmed.2022.105660
Kasem S, Saleh M, Qasim I, Hashim O, Alkarar A, Abu‐Obeida A, Gaafer A, Hussien R, AL‐Sahaf A, Al‐Doweriej A, Bayoumi F (2018). Outbreak investigation and molecular diagnosis of Lumpy skin disease among livestock in Saudi Arabia 2016. Transboundary Emerg. Dis. 65(2): 494-500. https://doi.org/10.1111/tbed.12769
Koirala P, Meki IK, Maharjan M, Settypalli BK, Manandhar S, Yadav SK, Cattoli G, Lamien CE (2022). Molecular characterization of the 2020 outbreak of lumpy skin disease in Nepal. Microorganisms, 10(3):539. https://doi.org/10.3390/microorganisms10030539
Kumar N, Barua S, Kumar R, Khandelwal N, Kumar A, Verma A, Singh L, Godara B, Chander Y, Kumar G, Riyesh T (2023). Evaluation of the safety immunogenicity and efficacy of a new live-attenuated lumpy skin disease vaccine in India. Virulence, 14(1) 2190647. https://doi.org/10.1080/21505594.2023.2190647
Leliso SA, Bari FD, Chibssa TR (2021). Molecular characterization of lumpy skin disease virus isolates from outbreak cases in cattle from Sawena District of Bale Zone Oromia Ethiopia. Vet. Med. Int., (1): 8862180. https://doi.org/10.1155/2021/8862180
Li Y, An Q, Sun Z, Gao X, Wang H (2023). Risk factors and spatiotemporal distribution of lumpy skin disease occurrence in the Asian continent during 2012–2022: an ecological niche model. Transboundary Emerg. Dis., (1): 6207149. https://doi.org/10.1155/2023/6207149
MARD (Ministry of Agriculture and Rural Development) (2020). Facility standards (TCCS 04: 2020/TY –DT) including testing procedures to detect viruses that cause Lympy Skin Disease. Ha Noi Vietnam.
OIE (World Organisation for Animal Health) (2017). Chapter 2.4.13. Lumpy skin disease OIE Terrestrial Manual 2017.
Rashid PMA, Sheikh MB, Raheem ZH, Marouf AS (2017). Molecular characterisation of lumpy skin disease virus and sheeppox virus based on P32 gene. Bulg. J. Vet. Med., 20(02): 131–140 https://pdfs.semanticscholar.org/8b2c/dfc3c5cf838423f8f78505d8364c06ffc354.pdf
Sameea Yousefi P, Dalir-Naghadeh B, Mardani K, Jalilzadeh-Amin G (2018). Phylogenetic analysis of the lumpy skin disease viruses in northwest of Iran. Trop. Anim. Health Prod., 50: 1851-1858. https://doi.org/10.1007/s11250-018-1634-3
Şevik M, Doğan M (2017). Epidemiological and molecular studies on lumpy skin disease outbreaks in Turkey during 2014–2015. Transboundary Emerg. Dis., 64(4): 1268-1279. https://doi.org/10.1111/tbed.12501
Şevik M, Avci O, Doğan M, İnce ÖB (2016). Serum biochemistry of lumpy skin disease virus‐infected cattle. BioMed. Res. Int., (1): 6257984. https://doi.org/10.1155/2016/6257984
Sprygin A, Artyuchova E, Babin YU, Prutnikov P, Kostrova E, Byadovskaya O, Kononov A (2018). Epidemiological characterization of lumpy skin disease outbreaks in Russia in 2016. Transboundary Emerg. Dis., 65(6): 1514-1521. https://doi.org/10.1111/tbed.12889
Tran AT, Tran HTT, Truong AD, Dang AK, Chu NT, Phan L, Phan HT, Nguyen HT, To NBT, Dang HV (2024). Molecular characterization of lumpy skin disease virus in North Central Vietnam during 2021 and early 2022. Vet. Ital., 60(1). https://doi.org/10.12834/VetIt.3233.22342.2
Tran HTT, Truong AD, Dang AK, Ly DV, Nguyen CT, Chu NT, Hoang TV, Nguyen HT, Nguyen VT, Dang HV (2021). Lumpy skin disease outbreaks in Vietnam 2020. Transboundary Emerg. Dis., 68(3): 977-980. https://doi.org/10.1111/tbed.14022
Trinh TBN, Nguyen VT, Nguyen TTH, Mai NTA, Le PN, Lai TNH, Phan TH, Tran DH, Pham NT, Dam VP, Nguyen TL (2022). Molecular and histopathological characterization of lumpy skin disease in cattle in northern Vietnam during the 2020–2021 outbreaks. Arch. Virol., 167(11): 2143-2149. https://doi.org/10.1007/s00705-022-05533-4
Tulman ER, Afonso CL, Lu Z, Zsak L, Kutish GF, Rock DL (2001). Genome of lumpy skin disease virus. J. Virol., 75(15): 7122-7130. https://doi.org/10.1128/jvi.75.15.7122-7130.2001
Tuppurainen E, Dietze K, Wolff J, Bergmann H, Beltran-Alcrudo D, Fahrion A, Lamien CE, Busch F, Sauter-Louis C, Conraths FJ, De Clercq K (2021). Vaccines and vaccination against lumpy skin disease. Vaccines, 9(10): 1136. https://doi.org/10.3390/vaccines9101136
Tuppurainen ES, Oura CA (2012). Lumpy skin disease: an emerging threat to Europe the Middle East and Asia. Transboundary Emerg. Dis., 59(1): 40-48. https://doi.org/10.1111/j.1865-1682.2011.01242.x
Wang J, Xu Z, Wang Z, Li Q, Liang X, Ye S, Cheng K, Xu L, Mao J, Wang Z, Meng W (2022). Isolation identification and phylogenetic analysis of lumpy skin disease virus strain of outbreak in Guangdong China. Transboundary Emerg. Dis., 69(5): 2291-2301. https://doi.org/10.1111/tbed.14570
Wolff J, Tuppurainen E, Adedeji A, Meseko C, Asala O, Adole J, Atai R, Dogonyaro B, Globig A, Hoffmann D, Beer M (2021). Characterization of a Nigerian lumpy skin disease virus isolate after experimental infection of cattle. Pathogens, 11(1):16. https://doi.org/10.3390/pathogens11010016
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