Submit or Track your Manuscript LOG-IN

Advances in Animal and Veterinary Sciences

AAVS_9_1_150-155

 

 

Research Article

 

Immune Status Against Newcastle Disease Virus in Backyard Poultry of Punjab Province, Pakistan

 

Muhammad Ali Qureshi1, Sami Ullah2*, Muhammad Zubair Latif1, Sadia Sarfaraz1, Sohail Ahmed3, Iffat Huma1, Ali Abbas1

1Veterinary Research Institute (VRI), Lahore, Pakistan; 2Department of Microbiology, University of Veterinary and Animal Sciences (UVAS), Lahore, Pakistan; 3Department of Clinical Sciences, University of Veterinary and Animal Sciences (UVAS), Lahore, Pakistan (Sub-campus, Jhang).

 

Abstract | Newcastle Disease (ND) is one of the most important health problem of commercial and backyard poultry. It is producing significant economic losses due to fatalities globally. The objective of the study was to carried out serum base investigation regarding the Newcastle disease Virus (NDV) antibody occurrence in different seasons of a year. The data were documented has current immune status of unvaccinated backyard poultry. A total of 1468 sera samples were collected from 32 districts of Punjab, Pakistan. Using Haemagglutination inhibition (HI) test, the serum Ab titer was measured and maximum seroprevalence (92%) was discovered in the Sargodha district, whereas Mianwali showed lowest seroprevalence (15.25%). Overall seropositivity (58.78%) was observed between 4log2 and 9log2 antibody titer and average geometric mean titer (GMT) was 16.59. Furthermore, the presence of serum base antibodies of NDV was found higher in summer season (64.50% with 21.38 GMT) but decreased in winter season (50% with 15.13 GMT). In the absence of the vaccine, the results provide a clear evidence of exposure to NDV to backyard poultry. Hence, systemic sero-surveillance is needed to counter the ever-increasing risk of NDV in backyard poultry.

 

Keywords | Newcastle disease virus (NDV), Backyard poultry, Antibody titer Haemagglutination inhibition (HI) test, Punjab, Pakistan

 

Received | July 13, 2020; Accepted | September 16, 2020; Published | December 10, 2020

*Correspondence | Sami Ullah, Department of Microbiology, University of Veterinary and Animal Sciences (UVAS), Lahore, Pakistan; Email: [email protected]

Citation | Qureshi MA, Ullah S, Latif MZ, Sarfaraz S, Ahmed S, Huma I, Abbas A (2021). Immune status against newcastle disease virus in backyard poultry of Punjab Province, Pakistan. Adv. Anim. Vet. Sci. 9(1): 150-155.

DOI | http://dx.doi.org/10.17582/journal.aavs/2021/9.1.150.155

ISSN (Online) | 2307-8316; ISSN (Print) | 2309-3331

Copyright © 2021 Qureshi et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

 

INTRODUCTION

 

ND causes a large number of outbreaks and economic losses in poultry industry throughout the world. (Alexander, 2001). Due to its tremendous economic losses and huge epidemics, World Organization for Animal Health (OIE) has listed it among the diseases that require immediate reaction upon recognition (OIE, 2012). This viral disease is extremely contagious and attacking several species of domestic and wild birds (Alexander et al., 2012). ND is caused by negative-sense single stranded RNA virus “avian paramyxovirus serotype-1 (APMV-1)” of genus Avulavirus under order Mononegavirales within the family Paramyxoviridae (King et al., 2011). NDV is divided into five pathotypes based on the severity of disease in chickens and these are namely, viscerotropic velogenic, neurotropic velogenic, lentogenic, mesogenic, and asymptomatic enteric form (Ahmed and Odisho, 2018).

 

ND is characterized by producing reproductive, digestive, nervous, and respiratory problems (Ashraf and Shah, 2014). Clinical signs depend upon various factors such as age of host, host species and strain of virus. Immune system, secondary infection and environmental stress also play vital role in disease progression (Al-Habeeb et al., 2013). Chickens show symptoms of anorexia, abnormal thirst, weakness and low egg production. In case of respiratory signs, there is nasal discharge along with cough, while digestive form includes green water diarrhea. Twisting of head and neck and paralysis of wings or legs is observed in nervous form (Bhaiyat et al., 1994). The NDV infect several species of domestic and wild birds regardless of variation in sex and age (Alexander et al., 2012; Iram et al., 2014).

 

Being an agro-country, livestock and poultry production are major profitable outcomes in the form of GDP in Pakistan. Pakistan has become the 11th largest poultry producer in the world with the production of 1,163 million broilers annually. Employment of more than 1.5 million people is linked to this industry. Around 89.84 million domestic poultry exist in Pakistan which occupies a place of pride among livestock enterprises due to its rapid monetary revenue (Economic Survey of Pakistan, 2019-20). In rural areas of many developing countries, poultry rearing is widely practiced (Alders et al., 1994) and considered as an important asset for a substantial source of protein in the form of eggs and meat. The seroprevalence study has revealed the existence of ND in backyard poultry in numerous countries (Couacy-Hymann et al., 2012; Molia et al., 2017; Alsahami et al., 2018). In Pakistan, results showed that ND is prevalent in domestic birds (Aziz-ul-Rahman et al., 2017) as major poultry hubs are located and growing in Punjab, Pakistan. Therefore, regulatory framework and monitoring services are needed to prevent health issues of poultry in concerned areas. The present study was conducted to evaluate the incidence of antibodies against NDV in backyard poultry which will help us to investigate epidemiology of virus in backyard and commercial poultry.

 

MATERIALS AND METHODS

 

Study area

Punjab province (31°N 72°E) is located along the northwestern edge of the geologic Indian plate in South Asia. Punjab province is located 139 m above sea level, and it is the most populous province (approximately 56% population of the Pakistan lives in this region). The 32 districts (mentioned in Table 1) was selected to investigate the current incidence of antibodies against NDV in backyard poultry. Through a serological survey of a one year, a total of 1468 blood samples of unvaccinated backyard poultry were obtained randomly from 32 districts of Punjab, Pakistan. About 5ml of blood was collected aseptically from wing vein and permitted to clot.

 

Haemagglutination inhibition (HI) test

To determine the antibody titer against ND virus, this test was performed using a reference strain of ND as control antigen obtained from Veterinary Research Institute (VRI), Ghazi Road Lahore. The blood from the chickens were taken and centrifuged at 1500 rpm for 10 minutes. HI test was performed according to the protocol described by (Alexander and Chettle, 1977) by making 2-fold serial dilution of serum samples using 4HA unit of NDV. The antibody titer of serum samples was measured by observing the button formation due to settling of RBC’s. The HI titer was determined as per standard operating procedures directed by manual published by OIE. Haemagglutination inhibition was considered as an end point at which sera were at maximum dilution. Samples were categorized as seronegative if sera had titer of <1:16 and sera with >1:8 titers were considered to be positive (Musa et al., 2009).

 

Statistical analysis

For descriptive statistics, collected data were entered in computer program MS EXCEL (Microsoft Co.). Geometric mean titer (GMT) of HI was calculated as designated by (Brugh et al., 1978) and to assess the immunity status, mean based univariate analysis was done through ANOVA in IBM SPSS ®.

 

RESULTS and Discussion

 

Overall, 1468 blood samples from different districts were tested by using the HI test. The antibody titer was observed up to 1:512. Most of the birds showed antibody titer up to 9log2. The average geometric titer for all districts was 16.59. The overall seroprevalence of ND in all districts of Punjab was 59%. These results are shown in Table 1.

 

The GMT titer and seroprevalence from age 20 weeks to >65 weeks was in range from 55.42% to 62.10%. The antibody titer was abundant in older birds as compared to young ones. These results showed that as age increased the GMT titer were also increased. Among four different groups, chickens with age 65 weeks showed high seroprevalence (62.10%) followed 51-65 weeks (58.69%), 36-50 weeks (58.29%) old birds and least seropositive were birds of age 20-35 as shown in Table 2.

 

The seroprevalence and GMT titer were also observed in different seasons in Punjab. The anti-NDV antibodies showed high existence in sera collected during summer season (64.50%) as compared to other seasons, 56.39% in autumn, 50% in winter and 63.79% in rainy seasons with 21.38, 16.22, 15.13 and 17.38 GMT, respectively as shown in Table 2.

 

Pakistan is endemic with NDV poultry because the virus prevailing not only in poultry (Munir et al., 2012) but also in other birds (Alexander et al., 2012). HI antibody titer against ND of 3log2 and above is commonly considered as positive for specific immunity (Allan and Gough,1974). Here is a conflict, because some authors used ≥ 2log2 (Biswas et al., 2009), 3log2 (Tadesse et al., 2005) and 4log2

 

Table 1: Overall results on geometric mean titer to NDV in backyard poultry reared in 32 District in Punjab.

 

Sr. Name of districts Sample size Log2 HI titre to NDV

GMT % Occurrence
No.     1:2 1:4 1:8 1:16 1:32 1:64 1:128 1:256 1:512    
1 Multan 50 8 11 12 4 - 5 7 3 - 13 38%
2 Khanewal 50 11 17 2 6 5 - 9 - - 9.57 40%
3 Jhang 50 6 10 13 1 12 8 - - - 11.64 42%
4 Muzaffar Garh 50 6 - 9 11 16 3 - 5 - 19.68 70%
5 Hafiz Abad 50 - 10 1 11 19 2 7 - - 21.97 78%
6 Rajan Pur 50 3 1 2 17 13 8 5 - 1 26.3 88%
7 Narowal 50 2 11 3 19 1 - 9 5 - 20.23 68%
8 Bahawal Pur 27 3 5 1 10 4 4 - - - 36.39 66.67%
9 Bahawal Nagar 57 - 10 7 - 16 11 6 6 1 32.36 70.18%
10 Sheikhupra 50 9 - 2 9 6 21 3 - - 23.6 78%
11 Okara 42 - 17 - 11 - 5 8 1 - 17.1 59.52%
12 Layyah 46 6 4 3 3 16 1 10 3 - 25.53 71.74%
13 Sargodha 50 4 - - 14 5 9 11 7 - 43.34 92%
14 Gujranwala 61 3 19 12 8 10 1 2 2 4 9.59 44.26%
15 Pakpattan 50 - 21 9 12 - 7 - 1 - 10.12 40%
16 Khushab 13 1 - 3 - 8 1 - - - 19.82 69.23%
17 Gujrat 60 - 12 12 10 9 15 2 - - 17.74 60%
18 Chiniot 51 17 13 9 1 2 2 5 1 1 7.46 24%
19 Bhakkar 50 10 3 - 6 14 7 7 3 - 22.59 74%
20 Lodhran 31 1 9 11 4 - - 5 1 - 11.97 32.26%
21 Sahiwal 34 - 11 7 6 5 - - 3 2 15.35 47.05%
22 Sialkot 50 - 21 1 3 5 1 9 10 - 24.55 56%
23 Vehari 50 - 24 13 9 1 3 - - - 7.57 26%
24 Faisal Abad 50 5 16 8 8 5 6 - 2 - 10.54 42%
25 Attock 50 6 - - 19 11 5 6 3 - 25.29 88%
26 Mianwali 16 2 9 1 1 3 - - - - 6.16 15.25%
27 Jehlum 50 13 7 11 8 2 4 5 - - 9.31 60%
28 Toba Tek Singh 39 8 1 2 1 8 8 6 3 2 30.34 71.79%
29 Kasur 50 3 2 7 4 5 19 6 4 - 36.22 76%
30 Rahim Yar Khan 50 - 6 29 9 5 1 - - - 9.97 30%
31 Nankana 35 2 - 4 4 7 13 3 2 - 35.32 71.42%
32 Dera Ghazi Khan 56 - 6 6 12 12 9 3 7 1 31.19 57.14%
Total 1468 129 276 200 241 225 179 134 72 12 16.59 58.78%

 


*Protective threshold; GMT: Geometric mean titer; NDV: Newcastle disease virus; HI: Hemagglutinin inhibition; C.I: Confidence Interval; NS: Non-significance.

 

Table 2: Age wise variation in observation of seropositivity against ND virus.

 

Age group (Weeks)

Sample size Anti-NDV antibodies titer by HI test

GMT Sero-prev alence Mean ± SE 95% C. I

21

22

23

24

25

26

27

28

29

       
20-35 332 26 80 42 88 51 11 24 9 1 16.98 55.42% 30.67±13.52 -4.08; 65.41
36-50 422 33 77 66 71 65 58 31 19 2 17.38 58.29% 41.0±11.36 11.80; 70.20
51-65 305 29 59 38 36 43 47 25 23 5 19.49 58.69% 29.83±6.31 15.62; 59.04
>65 409 41 60 54 46 66 63 54 21 4 20.89 62.10% 42.33±10.10 16.37; 68.30


Table 3: Seasonal variation in observation of seropositivity against ND virus.

 

Season Sample size Anti-NDV antibodies titer by HI test

GMT Sero-

prevalence

Mean ± SE 95% C. I

21

22

23

24

25

26

27

28

29

Autumn 383 34 88 45 63 54 43 34 19 3 16.22 56.39% 36.0±9.09 12.61; 59.39
Winter 348 23 70 81 58 34 35 30 16 1 15.13 50.00% 29.0±7.87 9.78; 51.22
Summer 400 40 59 43 59 58 64 45 28 4 21.38 64.50% 41.67±9.10 18.27; 65.06
Rainy 337 32 59 31 61 79 37 25 9 4 17.38 63.79% 29.49±12.04 4.88; 66.78

 


*Protective threshold; GMT: Geometric mean titer; NDV: Newcastle disease virus; HI: Hemagglutinin inhibition; C.I: Confidence Interval.

 

(Gutierrez-Ruiz et al., 2000) as cutoff titer for antibody production against the virus. Chickens which are reared in villages can withstand the infection without showing any clinical symptoms, thus acting as a potential source of infection for commercial chicken (Ananth et al., 2008).

 

Based on the serological evidence of the present study, Sargodha showed 92% higher seropositivity against NDV as compared to Miawali (15.25%) with overall seroprevalence as 58.78% with high GMT (16.59) as mentioned in Table 1. As similar findings have been revealed in previous reports on rural or village poultry with high seroprevalence 62-72% in Nigeria (Ezeokoli et al., 1984). Our finding is in agreement of previous investigation in Pakistan, as 98.07% and 100% occurrence of specific immunity against NDV for broilers and layer, were evaluated respectively (Numan et al., 2005). The current study results are also consistent with previous findings regarding serological survey in backyard poultry from Zambia (36.9%); (Alders et al., 1994), Zimbabwe (27%); (Kelly et al., 1994), Tanzania (46.1%); (Yongolo et al., 2002) South Africa (5%); (Thekisoe et al., 2003), Central Ethiopia (32.2%); (Tadesse et al., 2005), Ecuador (97%); (Hernandez-Divers et al., 2006) and Bangladesh (88%); (Biswas et al., 2009).

 

Age distribution in testing sera from the chicken was another risk factor in our study, because the prevalence of antibody titer to NDV increased with increasing age (East et al., 2006). As similar finding, a previous study was observed high seroprevalence of NDV in rural chickens from southern part of Bangladesh (Biswas et al., 2006). Similar to our findings, chickens with age >65 weeks showed high GMT (44.86) followed by 53-64 weeks (41.80), 41-52 weeks (39.05), 29-40 (37.13) weeks and least prevalent was in 17-28 weeks (33.11) of age groups (Hossain et al., 2010). Chicks revealed GMT 20.2 and adults had GMT 26.3 (Kemboi et al., 2013). It supported the fact that the prevalence of antibody titer to NDV increased with increasing age.

 

Kemboi et al., 2013 revealed high geometric mean antibody titer of chicks in wet season as compared to dry season. GMT results were 70.7 and 20.2 in wet season and dry season respectively. The matter of the seasonal influence is still debatable and may differ according to the geographical, dietary and socioeconomic situations. The ND peaks mostly occur at the start of the rainy season in Vietnam (Nguyen, 1991). Current findings also revealed the high seroprevalence in rainy season. Prevalence of NDV antibody titer of serum samples in layer and broiler birds was evaluated. Broiler chicken had 90%, 79.39%, 75.81% and 64.35% HI titer against NDV in summer, autumn, winter and rainy season respectively. Similarly, Layer chickens had 98.35%, 97.98%, 97.46% and 92.86% HI antibody titer in summer, winter, autumn and rainy season respectively that provides us clue regarding increased antibody titer against NDV in summer season (Hossain et al., 2010). ND outbreaks are linked to the variation of seasons (Martin and Spradbrow, 1991) because of high wind movement transfers infection from one poultry house or flock to the other (Manchang et al., 2004). Investigation and control measure related to NDV transmission should be future planning in those areas where it is endemic.

 

NDV is still causing major economic losses to our meat and eggs in various parts of Punjab which needs due attention by provincial and national health authority and livestock officers to come up with control and prevention policy. As, serological analysis is unable to demonstrate the type and nature of NDV strains in field conditions. Hence, there is a need for further work to understand the circulating strains or pathotypes and its epidemiology. Second, proper vaccination program against NDV may improve the backyard poultry production and will be helpful in successful control of diseases. So, for implementation of a successful NDV vaccination program, several parameters should be evaluated. Now, further study concerns to virological investigation is need of time to understand the interactions of virulent or avirulent virus and their impact on the backyard poultry production system.

 

ACKNOWLEDGMENT

 

We would like to thank the Director of Veterinary Research Institute, Ghazi Road Lahore, Pakistan for providing laboratory facilities and helping in sampling.

 

Author’s Contribution

 

All the authors have contributed in terms of giving their technical expertise to give a tenable shape to this manuscript.

 

Conflict of interest

 

The authors have declared no conflict of interest.

 

REFERENCES

 

  • Ahmed A, Odisho SM (2018). Isolation identification and pathotyping of newcastle disease viruses form naturally infected chickens in Iraqi Kurdistan region. Iraqi J. Agric. Sci., 49: 132-141.
  • Al-Habeeb MA, Mohamed M, Sharawi S (2013). Detection and characterization of Newcastle disease virus in clinical samples using real time RT-PCR and melting curve analysis based on matrix and fusion genes amplification. World, 6(5): 239-243. https://doi.org/10.5455/vetworld.2013.239-243
  • Alders R, Inoue S, Katongo J (1994). Prevalence and evaluation of Hitchner B1 and V4 vaccines for the control of Newcastle disease in village chickens in Zambia. Pre. Vet. Med., 21(2): 125-132. https://doi.org/10.1016/0167-5877(94)90001-9
  • Alexander DJ (2001). Newcastle disease. Br. Poult. Sci., 42(1): 5-22. https://doi.org/10.1080/713655022
  • Alexander D, Chettle N (1977). Procedures for the haemagglutination and the haemagglutination inhibition tests for avian infectious bronchitis virus. Avian Pathol. 6(1): 9-17.
  • Alexander DJ, Aldous EW, Fuller CM (2012). The long view: A selective review of 40 years of Newcastle disease research. Avian Pathol., 41(4): 329-335. https://doi.org/10.1080/03079457.2012.697991
  • Allan W, Gough R (1974). A standard haemagglutination inhibition test for Newcastle disease.(1). A comparison of macro and micro methods. Vet. Rec., 95(6): 120-123. https://doi.org/10.1136/vr.95.6.120
  • Alsahami A, Ideris A, Omar A, Ramanoon SZ, Sadiq MB (2018). Seroprevalence of Newcastle disease virus in backyard chickens and herd-level risk factors of Newcastle disease in poultry farms in Oman. Int. J. Vet. Sci. Med., 6(2): 186-191. https://doi.org/10.1016/j.ijvsm.2018.06.004
  • Ananth R, Kirubaharan JJ, Priyadarshini M, Albert A (2008). Isolation of Newcastle disease viruses of high virulence in unvaccinated healthy village chickens in south India. Int. J. Poult. Sci., 7: 368-373. https://doi.org/10.3923/ijps.2008.368.373
  • Ashraf A, Shah M (2014). Newcastle disease: Present status and future challenges for developing countries. Afr. J. Microbiol. Res., 8(5): 411-416. https://doi.org/10.5897/AJMR2013.6540
  • Aziz-ul-Rahman HM, Riaz T, Hussain B, Yousaf F, Saqalein M, Rasool M (2017). Seroprevalence of Newcastle disease virus (NDV) in commercial and domesticated birds: Pakistan during current surge of NDV. J. Infect. Mol. Biol., 4(4): 54-59. https://doi.org/10.14737/journal.jimb/2016/4.4.54.59
  • Bhaiyat M, Ochiai K, Itakura C, Islam M, Kida H (1994). Brain lesions in young broiler chickens naturally infected with a mesogenic strain of Newcastle disease virus. Avian Pathol., 23(4): 693-708. https://doi.org/10.1080/03079459408419038
  • Biswas P, Barua H, Uddin G, Biswas D, Ahad A, Debnath N (2009). Serosurvey of five viruses in chickens on smallholdings in Bangladesh. Prev. Vet. Med., 88(1): 67-71. https://doi.org/10.1016/j.prevetmed.2008.06.018
  • Biswas P, Uddin G, Barua H, Roy K, Biswas D, Ahad A, Debnath N (2006). Immune status of semi-scavenging Sonali chickens in Bangladesh against Newcastle disease. Livest. Res. Rural, pp. 18.
  • Brugh Jr M (1978). A simple method for recording and analyzing serological data. Avian Dis., pp. 362-365. https://doi.org/10.2307/1589552
  • Couacy-Hymann E, Kouakou A, Kouame C, Kouassi A, Koffi Y, Godji P, Nana P, Tarnagda Z, Akoua-Koffi C (2012). Surveillance for avian influenza and Newcastle disease in backyard poultry flocks in Cote d’Ivoire, 2007–2009. Rev. Sci. Tech., 31: 821-828. https://doi.org/10.20506/rst.31.3.2158
  • East I, Kite V, Daniels P, Garner G (2006). A cross-sectional survey of Australian chicken farms to identify risk factors associated with seropositivity to Newcastle-disease virus. Prev. Vet. Med., 77(3-4): 199-214. https://doi.org/10.1016/j.prevetmed.2006.07.004
  • Economic Survey of Pakistan (2019-20). Retrieved from http://www.finance.gov.pk/survey_1920.html
  • Ezeokoli C, Umoh J, Adesiyun A, Abdu P (1984). Prevalence of Newcastle disease virus antibodies in local and exotic chicken under different management systems in Nigeria. Bulletin of animal health and production in Africa Bulletin des sante et production animales en Afrique.
  • Gutierrez-Ruiz E, Ramirez-Cruz G, Gamboa EC, Alexander D, Gough R (2000). A serological survey for avian infectious bronchitis virus and Newcastle disease virus antibodies in backyard (free-range) village chickens in Mexico. Trop Anim. Health Prod., 32(6): 381-390. https://doi.org/10.1023/A:1005281619260
  • Hernandez-Divers SM, Villegas P, Prieto F, Unda JC, Stedman N, Ritchie B, Carroll R, Hernandez-Divers SJ ( 2006). A survey of selected avian pathogens of backyard poultry in northwestern Ecuador. J. Avian Med. Surg., 20(3): 147-158. https://doi.org/10.1647/2005-015R.1
  • Hossain KM, Ali MY, Yamato I (2010). Antibody levels against newcastle disease virus in chickens in Rajshahi and surrounding districts of Bangladesh. Int. J. Biol., 2(2): 102. https://doi.org/10.5539/ijb.v2n2p102
  • Iram N, Shah MS, Ismat F, Habib M, Iqbal M, Hasnain SS, Rahman M (2014). Heterologous expression, characterization and evaluation of the matrix protein from Newcastle disease virus as a target for antiviral therapies. Appl. Microbiol., 98(4): 1691-1701. https://doi.org/10.1007/s00253-013-5043-2
  • Kelly PJ, Chitauro D, Rohde C, Rukwava J, Majok A, Davelaar F, Mason PR (1994). Diseases and management of backyard chicken flocks in Chitungwiza, Zimbabwe. Avian Dis., pp. 626-629. https://doi.org/10.2307/1592089
  • Kemboi D, Chegeh H, Bebora L, Maingi N, Nyaga P, Mbuthia P, Njagi L, Githinji J (2013). Seasonal Newcastle disease antibody titer dynamics in village chickens of Mbeere District, Eastern Province, Kenya. Livest. Res. Rural, 25(10): 181.
  • King AM, Lefkowitz E, Adams MJ, Carstens EB (2011). Virus taxonomy: ninth report of the International Committee on Taxonomy of Viruses. Elsevier.
  • Manchang T, Abdu P, Saidu L (2004). Epidemiology and clinicopathologic manifestations of newcastle disease in Nigerian local chickens: Epidémiologie et manifestations clinicopathologiques de la maladie de Newcastle chez des poulets de race locale nigérians: Epidemiologica y manifestaciones clinico-patologicas de la enfermedad de Newcastle en los pollos de raza local nigerianos. Revue d’élevage et de médecine vétérinaire des pays tropicaux. 57(1-2). https://doi.org/10.19182/remvt.9902
  • Martin P, Spradbrow P (1991). The epidemiology of Newcastle disease in village chickens. Newcastle disease in village chicken. Canberra, Australia. Austra. Cent. Int. Agric. Res., pp. 40-45.
  • Molia S, Grosbois V, Kamissoko B, Sidibe MS, Sissoko KD, Traore I, Diakite A, Pfeiffer DU (2017). Longitudinal Study of Avian Influenza and Newcastle Disease in Village Poultry, Mali, 2009–2011. Avian Dis., 61(2): 165-177. https://doi.org/10.1637/11502-092616-Reg.1
  • Munir M, Cortey M, Abbas M, Afzal F, Shabbir MZ, Khan MT, Ahmed S, Ahmad S, Baule C, Ståhl K (2012). Biological characterization and phylogenetic analysis of a novel genetic group of Newcastle disease virus isolated from outbreaks in commercial poultry and from backyard poultry flocks in Pakistan. Infect. Gent. Evol., 12(5): 1010-1019. https://doi.org/10.1016/j.meegid.2012.02.015
  • Musa U, Abdu P, Dafwang I, Umoh J, Sa’idu L, Mera U, Edache J (2009). Seroprevalence, seasonal occurrence and clinical manifestation of Newcastle disease in rural household chickens in Plateau State, Nigeria. https://doi.org/10.3923/ijps.2009.200.204
  • Nguyen TD (1991). editor. Newcastle disease in village chickens control with thermostable oral vaccines. Proceeding (1991).
  • Numan M, Zahoor M, Khan H, Siddique M (2005). Serologic status of Newcastle disease in broilers and layers in Faisalabad and surrounding districts. Pak. Vet. J. S., 25(2): 55.
  • OIE U (2012). Manual of diagnostic tests and vaccines for terrestrial animals (mammals, birds and bees). See http://www. oie. int/manual-of-diagnostic-tests-and-vaccines-for-terrestrial-animals.
  • Tadesse S, Ashenafi H, Aschalew Z (2005). Seroprevalence study of Newcastle disease in local chickens in central Ethiopia. Int. J. Appl. Res. Vet. Med., 3(1): 25-29.
  • Thekisoe M, Mbati P, Bisschop S (2003). Diseases of free-ranging chickens in the Qwa-Qwa District of the northeastern Free State province of South Africa. J. S. Afr. Vet. Assoc., 74(1): 14-16. https://doi.org/10.4102/jsava.v74i1.490
  • Yongolo M, Machangu AM, Minga U (2002). Newcastle disease and infectious bursal disease among free-range village chickens in Tanzania. Characteristics and parameters of family poultry production in Africa. IAEA, Vienna.
  •  

     

     

    Advances in Animal and Veterinary Sciences

    November

    Vol. 12, Iss. 11, pp. 2062-2300

    Featuring

    Click here for more

    Subscribe Today

    Receive free updates on new articles, opportunities and benefits


    Subscribe Unsubscribe