COMPARISON BETWEEN HI AND ELISA IN DETECTING IMMUNE TITER FOLLOWING IBV VACCINATION

Document Type : Research article

Authors

1 Animal Health Res. Inst. Zagazig (Poult. Dis. Dept.)

2 Colleauge of Poult. And Rabbit Dis. (Vet. Hospital) Facult. Vet. Med. Zagazig Univ

Abstract

Serological assays can be used for evaluating immune response post vaccination, they can be also helpful in studying the status of maternally derived antibodies (MDA), and they can also give a diagnostic mirror for viral sero-epidemiology. In the present study comparison between hemagglutination inhibition test (HI) and Enzyme linked immunesorbant assay (ELISA) and their abilities to detect IBV antibodies at different circumstances (post vaccination, infection, and (MDA) was studied. HI test for IBV was performed against two distinct IBV serotypes namely (Mass- 41, 4/91). Since they are the major vaccines used commercially in the Egyptian market. ELISA was performed at two dilutions (1/100, 1/ 1000) which is nearly the reciprocal of dilution of (7 and 10) in HI test in a trial to set two points for comparing the obtained results From the two tests. ELISA test showed 100% sensitivity and specificity at dilution 1/100 and showed 80.96%, 95.5 % respectively at 1/1000 dilution. The sensitivity and specificity of HI test were 80.91%, 95% respectively when Mass-41 antigen was used and was 73.91 %, 62 % when 4/91 antigen was used .The difference in sensitivity and specificity with HI reflects it selectivity during serotyping and this picture will necessarily differ if samples were tested against other antigens like (D- 274, 1466,…..etc.,) this confirms our point of view for using HI in detecting immunity after IBV vaccination. It became obvious that ELISA result may be misleading as seen during studying MDA in sample (S-20), ELISA reading at 1/100 dilution was 12051±2018 with STDV(6384) and was 2406±754 with STDV(2385) at dilution 1/1000 their Conversion into two base log titer 1/10 will be 14.28±.317 and 14.56±.4 respectively on the other hand the HI titer was 4.5±.166 with STDV(0.5) when Mass – 41 antigen was used and it was 2.4±.476 with STDV (1.5) when antigen 4/91 was used, result of ELISA will be conflicting when devising a vaccination protocol for such flock.

Keywords


COMPARISON BETWEEN HI AND ELISA IN DETECTING IMMUNE TITER FOLLOWING IBV VACCINATION

 

BAYOUMIE, H.A.A. and HIKAL, M.A.G.

*Senior Researcher, Animal health Res. Inst. Zagazig (Poult .Dis. Dept.)

 ** Colleauge of Poult. And Rabbit Dis. (Vet. Hospital) Facult. Vet. Med. Zagazig Univ.

Email: heshambayoumie@yahoo.com

 

 

 

ABSTRACT

 

 

Received at: 5/11/2014

 

Accepted: 9/12/2014

 

 

Serological assays can be used for evaluating immune response post vaccination, they can be also helpful in studying the status of maternally derived antibodies (MDA), and they can also give a diagnostic mirror for viral sero-epidemiology. In the present study comparison between hemagglutination inhibition test (HI) and Enzyme linked immunesorbant assay (ELISA) and their abilities to detect IBV antibodies at different circumstances (post vaccination, infection, and (MDA) was studied. HI test for IBV was performed against two distinct IBV serotypes namely (Mass- 41, 4/91). Since they are the major vaccines used commercially in the Egyptian market. ELISA was performed at two dilutions (1/100, 1/ 1000) which is nearly the reciprocal of dilution of (7 and 10) in HI test in a trial to set two points for comparing the obtained results From the two tests. ELISA test showed 100% sensitivity and specificity at dilution 1/100 and showed 80.96%, 95.5 % respectively at 1/1000 dilution. The sensitivity and specificity of HI test were 80.91%, 95% respectively when Mass-41 antigen was used and was 73.91 %, 62 % when 4/91 antigen was used .The difference in sensitivity and specificity with HI reflects it selectivity during serotyping and this picture will necessarily differ if samples were tested against other antigens like (D- 274, 1466,…..etc.,) this confirms our point of view for using HI in detecting immunity after IBV vaccination. It became obvious that ELISA result may be misleading as seen during studying MDA in sample (S-20), ELISA reading at 1/100 dilution was 12051±2018 with STDV(6384) and was 2406±754 with STDV(2385) at dilution 1/1000 their Conversion into two base log titer 1/10 will be 14.28±.317 and 14.56±.4 respectively on the other hand the HI titer was 4.5±.166 with STDV(0.5) when Mass – 41 antigen was used and it was 2.4±.476 with STDV (1.5) when antigen 4/91 was used, result of ELISA will be conflicting when devising a vaccination protocol for such flock.

 

 

Keywords: IBV, HI, ELISA.

 

 


INTRODUCTION

 

Infectious Bronchitis Virus (IBV) is a highly contagious acute viral disease of the upper respiratory tract of chickens, it can also replicate in epithelial tissues of kidneys, gonads and oviduct of chickens causing their pathology and affecting the performance Lee et al. (2004).

 

IBV contains four structural proteins. The spike (S), and membrane (M) glycoproteins, a small membrane protein (E), and the internal nucleo-capsid protein (N) Spaan et al. (1988). The S protein is comprised of two subunits, S1, which forms the globular head of the spike protein, and S2, which anchors the S protein in the membrane. The S1 glycoprotein is known to induce the production of neutralizing and hemagglutination inhibition (HI) antibodies Ignjatovic and Galli (1995). The N protein is involved in cell-mediated immune responses while the M protein of IBV is not recognized as an immunogenic protein Seo et al. (1997).

 

Prevention of IB is achieved mainly through vaccination. Although in most cases IBV strains within a geographic region are distinct as mentioned byCallison et al. (2001), Gelb et al. (2005), Ignjatovic et al. (2006). Because IBV undergoes frequent changes in the viral genome, mainly in the S1 gene which  result in point mutations promoting the emergence of new antigenic variants Bochkov    et al. (2007), Ammayappan et al. (2008) and Lee      et al. (2008). The multiple IBV serotypes and its antigenic variation adds complexity to the proper  selection of vaccination protocol and proper selection of serologic method to analyses the test results Jackwood and De Wit (2013).

 

Vaccine strains should be selected to represent the antigenic spectrum of isolates in a particular region, because attenuated vaccines are known to have a limited range of protection, confined in many cases to homologous strains, rendering vaccination partially successful Lin et al. (2005). The use of heterologous vaccine strains, either simultaneouor sequentially, has broadened the protection spectrum in some cases Cook et al. (1999), but it is difficult to predict which combinations may confer the best protection. On the other hand, more virulent vaccine strains may have a broader range of protection, but their use is not recommended to avoid the risk of a disease outbreak Darbyshire (1985).

 

In the present study we were focusing on the value of HI test in detecting antibodies against IBV, since it can give an individual outlook for the immune titer for each vaccine used when distinct IB viral antigens are used, this enables corrective action whenever a problem is detected. On the contrary to ELISA which is giving one total outlook for IBV immune titer post vaccination.

 

MATERIALS

 

1 -Serum samples

Table (1) shows the vaccination history, source and number of the collected serum samples.


 

Table 1: Vaccination history of samples under investigation.

 

Lab. Ref.

No.

No. of

samples

Breed

Age at 

sample collection

Vaccination history

Age In days

Vaccines

S - 8

10

Bro.

24 D

1   D

9  D

14 D

HB1+IBV (H120)

IBV - Ma 5

IBV - 4/91

S - 14

22

Lay.

182 D

1   D

9  D

21 D

35 D

42 D

63 D

100 D

110 D

IB Primer(H120+D-274)

IBV - 4/91

IBV – Ma 5

Triple inact.(NDV,EDS76r,IBV)

IBV – H 120

IBV – Ma 5

IBV- H120

Triple inact.(NDV,EDS76,IBV)

S - 15

18

Lay.

280 D

1 D

8 D

15 D

40 D

80 D

102 D

IBV- H120

Triple inact.(NDV,EDS76,IBV)

IBV - 4/91

IBV – Ma 5

IBV - 4/91

Triple inact.(NDV,EDS76,IBV)

S – 16

4

Bro.

32 D

1   D

14 D

IB Primer(H120+D-274)

IB Primer(H120+D-274)

S – 18

4

Bro.

32 D

No data

Randum

S – 19

10

Lay.

245 D

6 D

13 D

HB1+IBV(H 120)

Triple inact.(NDV,EDS76,IBV)

S - 20

10

Bro.

1   D

---

MDA

S - 22

6

Lay.

245 D

1 D

8 D

15 D

40 D

80 D

102 D

H120

Triple inact.(NDV,EDS76,IBV)

IBV - 4/91

IBV – Ma 5

IBV - 4/91

Triple inact.(NDV,EDS76,IBV)

S  - 23

8

Bro.

24 D

1 D

7 D

IB Primer(H120+D-274)

HB1+IBV

Total

92 sample

 

Lay = layers     D=day             Bro = broilers         MDA=maternally derived antibodies

 


2 - Chicken RBCS

Chicken RBCS were obtained from three 28 day old specific antibody negative chicken (SAN) raised for this purpose.

 

3 - Saline

Sodium chloride 0.9% (ADWIC) ®, Sterile Pyrogen free.

 

4 - ELISA kit.

Commercial IBV ELISA kit (Proflock; Synbiotics Corporation). Lot.1202487

 

5 - IB viral antigen

IB viral antigens for HI test were obtained from GD Holland, {(Mass- 41) lot 11531-010811 exp. 8/2021, (4/91) lot 09601-020209 exp.8/2019.

 

6 - Negative serum

Sera from day old SPF chicks were used.   

 

METHODS

 

Haemagglutination inhibition test (HI).

HI tests, using IBV antigens (Mass-41 and 4/91) were performed as described by Villegas (1991), Villegas (2006). Serum dilutions ranged from 1:2 to 1:1024. All HI titers were expressed as Iog2 of the reciprocal of the highest serum dilution showing complete HI.

 

ELISA test

Serum samples were assayed in the commercial IBV ELISA systems 1:100 and 1:1000 dilutions, respectively, according to the manufacturer's instructions. Serum-to positive ratios (SP-ratios) were calculated, using the SP ratio formula:

 

From these SP-ratios, titers expressed as Iog2 values, were calculated using identical regression formulas (Synbiotics software) for both tests. Also used were the positive-negative SP cut-off values of 0.200 Synbiotics IBV ELISA according to the manufacturer recommendation.

OD sample — OD negative control

OD positive control — OD negative control

 

 

 

 

 


Statistical analysis.

Data were statistically analyzed as described by Snedecor and Cochran (1967). Using SPSS.16 computer program, value was used to determine significance.

                                                                                                  

RESULT

 

Results of the present work are illustrated in tables (2-7).


 


Table 2: The Geometric mean titer (GMT) of ELISA titer at dilution 1/100, and their conversion into two base logarithmic titer 1/10.

 

 

GMT of Elisa titer at dilution 1/100

Converting GMT of Elisa titer at dilution 1/100 multiplied *10

into two base log.titer 1/10 (Brugh 1978)

A - Portion

B-Portion

S - 8

S -14

S -15

S - 16

S - 18

S - 19

S - 20

S - 22

S - 23

S - 8

S -14

S-15

S - 16

S - 18

S - 19

S - 20

S - 22

S - 23

20356

5788

19443

5960

1355

15032

13455

9684

26322

15.3

13.5

15.2

13.5

11.4

14.8

14.7

14.2

15.7

8642

16496

11677

10619

6865

17853

4213

3785

22288

14

15

14.5

14.3

13.7

15.1

13.1

12.8

15.4

7497

17169

18039

5041

8722

19884

17483

8984

17853

13.8

15.1

15.1

13.4

14

15.2

15.1

14.2

15.1

11099

13717

22869

1269

20861

22694

11275

4441

7648

14.4

14.7

15.4

11.4

15.3

15.4

14.5

16

13.9

9746

22869

23132

 

 

16702

16857

4612

15681

14.2

15.4

15.5

 

 

15

15

13.1

14.9

17747

20189

21455

 

 

23249

13861

6415

16137

15.1

15.3

15.4

 

 

15.5

14.7

13.6

14.9

8286

22869

17481

 

 

13813

11727

 

1688

14

15.4

15.1

 

 

14.7

14.5

 

11.7

76686

22345

22201

 

 

7478

2330

 

9935

15.9

15.4

15.5

 

 

13.8

12.2

 

10.9

10147

20664

14126

 

 

3901

6327

 

 

14.3

15.3

14.7

 

 

12.9

13.6

 

 

3974

20078

17169

 

 

8783

22985

 

 

12.9

15.2

15

 

 

14.1

15.4

 

 

 

21427

21798

 

 

 

 

 

 

 

15.3

15.4

 

 

 

 

 

 

 

21002

22172

 

 

 

 

 

 

 

15.3

15.4

 

 

 

 

 

 

 

16086

20468

 

 

 

 

 

 

 

14.9

15.3

 

 

 

 

 

 

 

21569

21970

 

 

 

 

 

 

 

15.4

15.4

 

 

 

 

 

 

 

19279

22259

 

 

 

 

 

 

 

15.2

15.4

 

 

 

 

 

 

 

20636

17510

 

 

 

 

 

 

 

15.3

15.1

 

 

 

 

 

 

 

23220

16444

 

 

 

 

 

 

 

15.5

15

 

 

 

 

 

 

 

21256

17143

 

 

 

 

 

 

 

15.3

15

 

 

 

 

 

 

 

14077

 

 

 

 

 

 

 

 

15.3

 

 

 

 

 

 

 

 

21856

 

 

 

 

 

 

 

 

14.7

 

 

 

 

 

 

 

 

20973

 

 

 

 

 

 

 

 

15.4

 

 

 

 

 

 

 

 

21455

 

 

 

 

 

 

 

 

15.3

 

 

 

 

 

 

 

10

22

18

4

4

10

10

6

8

10

22

18

4

4

10

10

6

8

Table 3: The Geometric mean titer (GMT) of ELISA titer at dilution 1/1000, and their conversion into two base logarithmic titer 1/10.

 

GMT of Elisa titer at dilution 1/1000

Converting GMT of Elisa titer at dilution 1/1000 multiplied *100    into two base log. titer 1/10 (Brugh 1978)

A-Portion

B-Portion

S - 8

S -14

S-15

S - 16

S - 18

S - 19

S - 20

S - 22

S - 23

S - 8

S -14

S-15

S - 16

S - 18

S - 19

S - 20

S - 22

S - 23

8041

4408

8596

280

0

5664

2155

237

4252

15.9

15.9

16.9

12.4

0

16

15.3

15.5

16

212

4836

2760

1489

1894

5912

525

405

9322

12.1

15.9

12.4

14.8

15.2

16

13.3

16

18

237

3577

5028

276

4728

6866

4660

819

7631

12.2

15.9

15.9

12.4

15.9

16

13.1

14

18

1272

4501

12024

331

7892

1077

1077

289

1584

14.5

15.9

18

12.7

17.9

14.3

14.3

12.5

14.9

805

2378

14212

 

 

0

1999

0

3723

13.9

15.5

18

 

 

 0

15.2

 0

15.9

1847

3784

7810

 

 

5406

2482

675

4986

15.2

15.9

17

 

 

16

15.6

13.7

16

1177

13718

3689

 

 

4890

1866

 

930

14.5

16

16

 

 

16

15.1

 

14.1

1413

8191

10072

 

 

7696

469

 

1305

14.8

17

17

 

 

17

13.1

 

14.6

233

5014

2814

 

 

2870

644

 

 

12.1

15.9

15.7

 

 

15.8

13.6

 

 

0

5693

2673

 

 

2009

8191

 

 

0

15.9

15.7

 

 

15.2

17

 

 

 

5477

9358

 

 

 

 

 

 

 

15.9

17

 

 

 

 

 

 

 

11504

12160

 

 

 

 

 

 

 

17

18

 

 

 

 

 

 

 

1980

7975

 

 

 

 

 

 

 

15.3

17

 

 

 

 

 

 

 

1838

12770

 

 

 

 

 

 

 

15.1

18

 

 

 

 

 

 

 

2524

15821

 

 

 

 

 

 

 

15.6

18

 

 

 

 

 

 

 

8630

9393

 

 

 

 

 

 

 

16

17

 

 

 

 

 

 

 

   17925

  3577

 

 

 

 

 

 

 

18

16

 

 

 

 

 

 

 

9517

7054

 

 

 

 

 

 

 

17

17

 

 

 

 

 

 

 

2970

 

 

 

 

 

 

 

 

17

 

 

 

 

 

 

 

 

2429

 

 

 

 

 

 

 

 

15.8

 

 

 

 

 

 

 

 

5222

 

 

 

 

 

 

 

 

15.5

 

 

 

 

 

 

 

 

8325

 

 

 

 

 

 

 

 

16

 

 

 

 

 

 

 

 

Table 4: Haemagglutination inhibition (HI) titer of examined samples using Mass-41 and 4/91 IBV antigens

 

Titer values

HI Mass-41

HI- 4/91

S - 8

S -14

S-15

S - 16

S - 18

S - 19

S - 20

S - 22

S - 23

total

S - 8

S -14

S-15

S - 16

S - 18

S - 19

S - 20

S - 22

S - 23

total

Number of values

Number of values

 

0

 

 

 

1

 

 

 

 

3

4

 

 

 

4

1

10

1

 

8

24

1

 

 

 

 

 

 

 

 

5

5

 

 

 

 

1

 

2

 

 

3

2

1

 

 

 

1

2

 

 

 

4

5

 

 

 

1

 

2

 

 

8

3

2

 

 

 

2

2

 

 

 

6

 

 

 

 

1

 

3

 

 

4

4

1

5

 

 

1

2

5

 

 

14

5

4

 

 

 

 

1

3

 

13

5

3

8

 

1

 

3

5

 

 

20

 

8

 

 

 

 

1

3

 

12

6

2

5

1

 

 

1

 

 

 

9

 

6

9

 

 

 

 

 

 

15

7

1

2

5

2

 

 

 

 

 

10

 

3

 

 

 

 

 

 

 

3

8

 

2

12

 

 

 

 

 

 

14

 

1

9

 

 

 

 

 

 

10

9

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

10

 

 

 

 

 

 

 

6

 

6

 

 

 

 

 

 

 

 

 

 

total

10

22

18

4

4

10

10

6

8

 

10

22

18

4

4

10

10

6

8

 

 

Cut off values

 

                                           

 

Table 5:The Geometric mean titer (GMT) of ELISA titer at dilution 1/100, 1/1000 and their conversion into two base logarithmic titer 1/10.

 

 

S - 8

S -14

S -15

S - 16

S - 18

S - 19

S - 20

S - 22

S - 23

A

17418±6759

19319±869

19279±772

5722±1922

9450±4112

14938±2060

12051±2018

6320±1021

14694±2826

STDV

21376.7

4078.2

3277.1

3844.05

8225

6514.3

6384

2501.8

7994.3

B

14.39±.2

15.14±.09

15.1±.06

13.15±.6

13.6±.8

14.65±.25

14.28±.317

13.9±.465

14.1±.6

STDV

.851

.427

.278

1.23

1.6

.81

1.004

1.139

1.7

C

1523.7±750*

6110±883

8210±980

594±298*

3628.5±1721

4239±818

2406±754

404±122

4216±1075**

STDV

2372.4

4144.8

4160.6

597.1

3442.9

2588

2385

299.9

3041.8

D

12.52±1.45

16.09±.14

16.7±.319

13.07±.57

12.25±4.1

14.23±1.59

14.56±.4

11.9±2.44

15.9±.51*

STDV

4.6

.686

1.36

1.15

8.2

5.04

1.29

5.98

1.45

E

4.7±.5

5.45±.26

7.61±

4.75±1.6

3±.405

3.9±.433

4.5±.166

10

0.63±.18

STDV

1.766

1.22

0.6

3.3

0.81

1.37

0.5

0

0.517

F

3±.33

5.5±.23

7±1.02

0

1.5±.64

0

2.4±.476

4.5±.22

0

STDV

1.05

1.1

1.02

0

1.29

0

1.5

0.54

0

 

A=GMT of Elisa titer at dilution 1/100  *=0.05                    **=0.01.

B=Converting GMT of Elisa titer at dilution 1/100 into two base logarithmic titer 1/10 (Brugh 1978).

C=GMT of Elisa titer at dilution 1/1000                STDV. =standard deviation

D=Converting GMT of Elisa titer at dilution 1/1000 into two base logarithmic titer 1/10 (Brugh 1978).

E= Mean HI -Mass 41.

F= Mean HI -4/91

 

Table 6: Shows the sensitivity % and specificity % of applied serological tests.

 

 

ELISA at dilution 1/100

ELISA at dilution 1/1000

HI using mass-41

HI using 4/91

* Sensitivity %

100%

80.96%

80.91%

73.91%

**Specificity %

100%

95.5%

85%

62%

 

* Sensitivity =% of positives / tested samples.       **specificity = % of negatives / tested samples

 

Table 7: Shows the correlation between number and varieties of given vaccines, beside intervals up till sample collection and the recorded serological values with different serological tests.

 

 

Number and varieties of vaccinal strains given for examined flocks

Time elapsed  from vaccination till sampling

HI titers

ELISA

two base log.titer 1/10

Classical  vaccinal strains

Triple inactivated vaccine

Variant vaccinal strains

H 120

Ma 5

Mass-41

4/91

D 274

Mass- 41

4/91

1/100 dilution

S - 8

-

-

-

10 days

4.7

3

14.39

S -14

ш

п

-

п

72 days

5.45

5.5

15.14

S - 15

-

п

п

-

178 days

7.61

7

15.1

S - 16

п

-

-

-

-

п

17 day

4.75

0

13.15

S - 18

Random

3

1.5

13.6

S - 19

-

-

-

-

232 days

3.9

0

14.65

S - 20

MDA

4.5

2.4

14.28

S -22

-

п

п

-

143 day

10

4.5

13.9

S - 23

п

-

-

-

-

-

17 day

0.63

0

14.1

 

I = administered once                             П = administered twice           Ш = administered three times   - = non

 

 

DISCUSSION

 

Prevention of IB relies mainly on vaccination, however it does not confer full protection against the heterologous IB variant strains. To devise a successful vaccination protocol against IBV it is necessary to isolate the circulating viruses in the locality and study their relatedness and cross protection Callison et al. (2001). The various viral strains of IB can be classified according to serotype, genotype and protectotype. using virus neutralization, or by genotyping, using RT PCR together with sequencing or a second specific-primer PCR, or, more rarely, using restriction fragment length polymorphism (RFLP) Worthington et al. (2008), this may not be feasible in developing countries and it is time consuming. Other workers such as Cook et al. (1999) though of combing classical and variant vaccines to widen the protection against IBV but this was not completely successful due to  the large number of IBV serotypes and the lack of complete cross protection.

 

We thought that it might be helpful to use HI for the evaluation of the immune titer for two most prevalent vaccine strains in the Egyptian market, since this test is efficient in serotyping which will helpful in studying sero-conversion post vaccination with these strains, this procedure will allow a corrective procedure when vaccinal failure is detected, and we also suggested rules for interpretation of the HI and ELISA results.

 

The multiple IBV serotypes and its antigenic variation, adds complexity to the selection of an appropriate serologic method and to the analysis of test results. All IBV serotypes would seem to have common epitopes (group-specific antigens), which is given the moderately high amino acid sequence identity within the N and M proteins and the S2 part of the spike protein. IBVs also induce type-specific antibodies, determined by epitopes of the S1 protein Cavanaghand Gelb (2008). Jackwood and De Wit (2013).

 

The advantage of serological studies based on tests such as (HI and ELISA) is the historical aspect that they bring to the clinical case, since their results can measures the reaction of the bird to the disease causing agent over a period of time, whereas direct diagnostics such as (PCR) requires the presence of the virus at the very moment of sampling Auvigne     et al. (2013).

 

ELISA testing is unable to differentiate the different infectious bronchitis serotypes, as this method involves antibody binding to group-specific as well as type- specific antigensMockett and Darbyshire (1981). Macnaughton et al. (1981). The antibody response assessed by HI and VN, may be used as an aid to the diagnosis of the predominant serotype present. Dhinakar and Jones (1997), Mockett and  Darbyshire (1981).

 

In poultry, high specificity of serological tests is more important than high sensitivity, since low sensitivity can be compensated for, by using a higher number of blood samples. The sensitivity could be calculated as the percentages of positives while the specificity could be calculated as the percentage of negatives in the tested samplesDe Wit et al. (1997), De Wit (2000), Auvigne et al. (2013). In the present study the sensitivity of ELISA at dilution 1/ 100 was 100 %, and this percent was 80.96% when the dilution was 1/ 1000, comparatively the HI test performed using Mass-41 antigen at cut off value 2 revealed that 80.92 % of the examined samples were positive for IBV antibodies and this percent was 73.91 % when the 4/ 91 IBV antigen was used. The cut off value in the present study was set as 22 (table -4) on the contrary for the previous work of Alexander and Chettle (1977), De wit et al. (1997) because Villegas (1991), Villegas (2006) were using 8 HA units ,while  Alexander and Chettle (1977), De wit et al. (1997) used 4 HA units of  IBV antigen for the test, as for the specificity in the present study the percent of negative reactors in the examined samples using ELISA were (0/92) at dilution 1/100 and was (4/92) i.e. 4.3% when ELISA was performed at dilution 1/1000, and when HI was performed it was (14/92) i.e. 15.2% using Mass-41 antigen, and (35/92) i.e. 38% with 4/91 antigen. De wit et al. (1997) found that ELISA is moderately sensitive but highly specific when examining sera from non-vaccinated birds ,and it is sensitive with variable specificity when examined sera were from vaccinated birds., as for HI test the results will depend on the cut off values and they recorded a specificity of 55 - 100% and wide variation in sensitivity. These result fortifies our findings, the wide variation in sensitivity is result of using distinct antigen i.e. (4/91 or Mass-41).

 

ELISA showed 100% sensitivity and specificity at dilution 1/100 and showed 80.96%, 95.5 % respectively at 1/1000 dilution. The sensitivity and specificity of HI were 80.91%, 95% respectively when Mass-41 antigen was used and was 73.91 %, 62 % when 4/91 antigen was used. The difference in sensitivity and specificity with HI reflects it selectivity during serotyping and this picture will necessarily differ if samples were tested against other antigens like (D- 274, 1466,…..etc.,) this confirms our point of view for using HI in detecting immunity after IBV vaccination.

 

It became obvious that ELISA result may be misleading as seen during studying MDA in sample (S-20), ELISA reading at 1/100 dilution was 12051±2018 with STDV (6384) and was 2406±754 with STDV(2385) at dilution 1/1000 their Conversion into two base log titer 1/10 will be 14.28±.317 and 14.56±.4 respectively on the other hand the HI titer was 4.5±.166 with STDV(0.5) when Mass – 41 antigen was used and it was 2.4±.476 with STDV (1.5) when antigen 4/91 was used, result of ELISA will be conflicting when devising a vaccination protocol for such flock.

 

The rational for ELISA at dilution 1/1000 is the high immune titers observed when dilution was 1/100, and because that 4 out of 92 examined sample were negative (table -3) although 1:1000 in ELISA is very near for 1:1024 (10th dilution of HI starting 1:2) at which  6 samples out of 92 were only positive and the remaining  84 samples ended before the 9th dilution, this had led us to carry on ELISA at dilution 1: 100 which is very near for 1:128 (7th dilution of HI starting 1:2) all examined samples were positive for ELISA and HI using Mass-41 IBV antigen but a different picture was observed when HI using 4/91 IBV antigen this confirms the hypothesis that with HI you can observe a distinctive pictures for each vaccinal strain used .although examined samples were (100%) positive for ELISA and HI using Mass-41 IBV antigen at dilution 1:100 and were (13/93) i.e. 14.13% when HI was performed using 4/91 antigen, and this confirms our point.

 

The ELISA technique is a sensitive serological method gives earlier reactions and higher antibody titers than other testsMockett and Darbyshire (1981).Commercial ELISA kits used for monitoring serum antibody responses against IBV are broadly cross-reactive among serotypes and allow for general serological monitoring of vaccinal responses and field challenges but it lacks strain specificity Karaca and Naqi. (1993), De Wit et al. (1997) commercially available. ELISAs detects IBV antibodies within one week of infection, earlier than by HI or VN tests Marquardt et al. (1981), Mockett and Darbyshire (1981), De Wit et al. (1997), De Wit (2000).

 

HI should be used for identifying serotype-specific responses to vaccination and field challenges in young growing chickens. Because with multiple infections and vaccinations, the sera of breeders and layers will be cross-reactive thus its results cannot be used with a high degree of confidence De Wit et al. (1998)., but the low cost, simple test equipment and speed of the HI test makes it a very useful procedure for routine diagnosis; the limitations must simply be borne in mind, and alternative analytical techniques should be at hand when doubt arises De Wit et al. (1997).

 

Standard protocol for HI for IBV has been describedVillegas (1991), Villegas (2006) with minor changes  from the protocol of Alexander and chettle (1977), the test procedure is based on that standard strains and isolates of IBV will agglutinate chicken red blood cells RBCs after neuraminidase treatment Ruano      et al. (2000), Schultze et al. (1992). The strain selected to produce antigen may be varied, depending on the requirements of diagnosis.  In the present study sera were analyzed by HI for two serotypes (Mass41and 4/91). The serum samples underwent serial halving dilution and were mixed with an equivalent amount of antigen. After incubation (30 min at 20°C), washed chicken red blood cells (WCRBCS) from SAN chickens, prepared with an anticoagulant, were added. After incubation (40mn at 20°C), the results were read by inclination of the plaques and observation of the HI. The antibody titer of the serum sample, expressed in log2, corresponds to the highest serum dilution leading to complete inhibition. The highest tested titer is 10, the well 11 was left for virus control and well 12 was left for (WCRBCS) control. The validity of results was ascertained by using a negative serum control sample that should not have a titer above or equal to 2 log2.

 

Haemagglutinating antigen for the HI test could be prepared from chorioallantoic fluid harvested from IBV-inoculated embryonated chicken eggs. Neuraminidase type V in PBS (pH7.2 at 1, 0 units/ml final concentration is used to treat IBV for 30 min at 37 C) Ruano et al. (2000). Antigen titration is performed in standard U-bottom 96-well microtiter plates using (WCRBCS)close range of an initial series of dilutions, i.e. 1/3, 1/4, 1/5, 1/6, etc. gives more accurate initial titration. Treatment of IBV with bacterial phospholipase C was initially thought to enable the virus to agglutinate (WCRBCS) Alexander and Chettle (1977), King and Hopkins (1984). However, HA antigens produced using highly purified phospholipase C preparations often had considerably lower titers than those produced using unpurified phospholipase C preparations. Subsequent studies Ruano et al. (2000). Shultze et al. (1992)determined that treatment of IBV with purified neuraminidase preparations consistently produced high-titer HA antigens. These findings suggested that the unpurified phospholipase C preparations were contaminated with neuraminidase, this comparison will be the subject of our investigation during the intended antigen preparation trials.

 

Auvigne et al. (2013) used typology of the flock profiles using clustering methods. This allows grouping the flocks according to their resemblance without posing any prior hypothesis other than those used for the general study design (choice of flocks, age at sampling, sampling and testing). As a first step, a principal components analysis (PCA) was carried out to allow studying the overall variability of the dataset and creating new uncorrelated variables, summarizing information that may have a biological sense and that may contribute to differentiate groups. The study of the variability percentage explained by each of this new variables and their biological signification allow determining which of these new variables have to be retained for the rest of the analysis. As a second step, ascending Hierarchical Clustering (HC) was performed. For calculation of distances between individuals and then assembling them in groups according to proximity. The variables used in the HC to calculate the distances are the coordinates of the flocks on the retained axes by the PCA. The HC leads to a dendrogram used to define the optimal cluster number. This choice depends on the clearness of the separation between the dendrogram branches and on the number of flocks in each group. As a third step, the means of the new variables created at the PCA step are calculated for each of the groups and, using the k-means method, each flock is reassigned to the group with the nearest mean. The representation of these groups on the PCA axes allows determining the discriminatory axes between groups. If certain axes turn out to be non-discriminatory, a new iteration of the analysis is performed. Finally, as a fourth step, the distribution characteristics of the 6 mean serological titers within each group are described and the biological meaning of these groups is investigated. Auvigne et al. (2013) mentioned the typological analysis allows interpretation of the results in spite of the existence of cross reactions. However, this method requires certain choices (number of axes, number of clusters) that have an impact on the final result, and it is not an absolute classification. However, the fact that the obtained classification is coherent with the data of experimental infections, even though the bibliographical data were not used for the classification, is in favor of its relevance. In the present study we were not able to use  hierarchical clustering because setting a cut off values  will not allow to consider values below this cut off  .In the present study we used the EXCEL sheets to calculate what is presented in (table -5).

 

ELISA titers as seen in  (table 2,3) couldn't be evaluated as it is, and It was also noticed the standard error of the  values was very high ranging from (4 to 43%) which is a very high values indicative of nonhomogeneous titers Kurian et al. (2012) examined heat treatment, repetitive freezing and thawing and three levels of severity of hemolysis as a sample mishandling treatments simulated different conditions that might occur during routine blood collection, transport or storage in a clinical practice setting. Each mishandling treatment was experimentally applied under laboratory conditions and then samples were assayed for antibodies against IBV, AEV and CAV using commercial ELISA kits. And found that severe hemolysis had the most consistent detrimental effect on ELISA performance, producing results that were significantly different from the reference standard in all three ELISAs, although the direction of the effect varied (less positive for the IBV and CAV assays; more positive for the AEV assay). Moderate levels of hemolysis had a similar, but less consistent, effect to that of severe hemolysis, producing results that were significantly different from the reference standard only for the IBV (less positive) and AEV (more positive) ELISAs. Repetitive freeze–thawing also produced a significant effect on ELISA results for IBV (less positive) and AEV (more positive). The IBV ELISA appeared to be most susceptible to the effects of serum maltreatment. The findings from this study suggest that unpredictable variation in the results of ELISAs can occur due to different sample mishandling treatments.

 

In the present study we converted the obtained ELISA results at dilution 1/100 in (table-2) and that at dilution 1/1000 (table -3) into its two base logarithmic titer 1/10(Brugh 1978), to obtain a numerical values that well facilitate the comparison between the two tests as performed by De Wit et al. (1997) After converting the GMT of ELISA titer 1/100 multiplied by10 into its base log titer 1/10 (Brugh 1978), you can observe that the figure 15.4 will represent the ELISA reading of (20973-22869) (table -2), this numeric values were very high compared to that of HI at dilution 7 or 10 which were zero in most examined samples.

 

In the present study serum samples submitted for investigation were collected from different flocks receiving different vaccination programs (table 1), the time interval from the last vaccine used until sample collection ranged from 10 to 232 day post vaccinations (Table-6), the mean two base log titer of ELISA at dilution 1/100 was ranging from (13.16 -15.14) despite of the number of vaccine administration which ranged from (2 up to 9 times including inactivated vaccine) (table -6). It is also apparent that this high titers was observed in samples (S – 16,19 and 23) these samples were from flocks that did not receive any variant vaccines, this apparent high titer masks the fact that birds are at risk if challenged with a variant. Comparatively HI titers observed were zero in sample (S- 16, 19 and 23) since their flock did not receive any vaccine of such strains so, although ELISA gave a sensitivity percent of 100%, 80.96% at the examined dilution (1/100, 1/1000) respectively and it also gave a specificity (100%, 95.5) at the same dilutions, but this is not logic for the obtained results compared to HI results.

 

REFERANSES

 

Alexander, DJ. And Chettle, N.J. (1977): Procedures for HA and HI for avian IBV.Avian Pathl. 6: 9-17.

Ammayappan, A.; Upadhyay, C.; Gelb, J Jr. and Vakharia, VN. (2008): Complete genomic sequence analysis of IBV Ark DPI strain and its evolution by recombination. Virol J. 5: 157.

Auvigne, V.; Gibaud, S.; Leger, L.; Malher, X.; Currie, R. and Riggi, A. (2013): A longitudinal study of incidence of IBV in France using strain-specific HI & cluster analysis.Revue Méd. Vét, 164: 417- 424.

Bochkov, YA.; Tosi, G.; Massi, P. and Drygin, VV. (2007): Phylogenetic analysis of partial S1 and N gene of IBV isolates from Italy revealed genetic diversity and recombination. Virus Genes. 35: 65–71.

Brugh, MA. Jr. (1978): A simple method for recording and analyzing serological data. Avian Dis.22: 362- 365.

Callison, SA.; Jackwood, MW. and Hilt, DA. (2001): Molecular characterization of IBV isolates foreign to the United States and comparison with USA isolates. Avian Dis. 45: 492–499.

Cavanagh, D. and Gelb, J. (2008): IBV. In diseases of poultry 12th ed. Editor Saif. Y.M.pp.        117-135.

Cook, JKA.; Orbell, SJ.; Woods, MA. and Huggins, MB. (1999): Breadth of protection of the respiratory tract provided by different live-attenuated infectious bronchitis vaccines against challenge with infectious bronchitis viruses of heterologous serotypes. Avian Pathol. 28: 477–485.

Darbyshire, JH. (1985): A clearance test to assess protection in chickens vaccinated against avian IBV. Avian Pathol. 14: 497–508.

De Wit, JJ. (2000): Detection of infectious bronchitis. Avian Pathology 29: 71, 93.

De Wit, JJ.; Mekkes, DR.; Kouwenhoven, B. and Verheijden, JH M. (1997):Sensitivity and specificity of serological tests for detection of IBV induced antibodies in broilers. Avian Pathol 26: 105-118.

De Wit, JJ.; Mekkes, DR.; Koch, G. and Westenbrink, F. (1998): Detection of specific Igm antibodies to IBV by an antibody capture ELISA. Avian Pathol 27: 2 155-160.

Dhinakar, RAJ G. and Jones, RC. (1997): Infectious bronchitis virus: immunopathogenesis of infection in the chicken. Avian Path. J. Of the W.V.P.A .26: 677‑706.

Gelb, JJ.; Weisman, Y.; Ladman, BS. and Meir, R. (2005): S1 gene characteristics and efficacy of vaccination against IBV field isolates from the USA and Israel (1996–2000). Avian Pathol. 34: 194–203.

Ignjatovic, J. and Galli, L. (1995): Immune responses to structural proteins of avian infectious bronchitis virus. Avian Pathol. 24: 313–332.

Ignjatovic, J.; Gould, G. and Sapats, S. (2006): Isolation of a variant IBV in Australia that further illustrates diversity among emerging strains. Arch Virol.151: 1567–1585.

Jackwood, MW. and De Wit, JJ. (2013): IBV.In: Dis. of Poult. 13th edition. Edit. David E. Swayne pp 139 -160.

Karaca, K. and Naqi, SN. (1993): A monoclonal antibody-based ELISA to detect serotype-specific IBV antibodies. Vet Microbiol 34: 249-257.

King, DJ. and Hopkins, SR. (1984): Rapid serotyping of IBV isolates with the HI. Avian Dis. 44: 325-335.

Kurian, A.; Neumann, EJ.; Hall, WF. and Marks, D. (2012):Effects of blood sample mishandling on ELISA results for infectious bronchitis virus, avian encephalomyelitis virus and chicken anaemia virus.The  Vet.  Journal 192: 378–381.

Lee, CW.; Brown, C.; Hilt, DA. and Jackwood, MW. (2004): Nephropathogenesis of chickens experimentally infected with various strains of IBV.J. Vet. Med. Sci. 66: 835–840.

Lee, EK.; Jeon, WJ.; Lee, YJ.; Jeong, OM.; Choi, JG.; Kwon, JH. and Choi, KS. (2008): Genetic diversity of avian infectious bronchitis virus isolates in Korea between 2003 and 2006. Avian Dis. 52: 332–337.

Lin, KY.; Wang, HC. and Wang, CH. (2005): Protective effect of vaccination in chicks with IBV against field virus challenge. J. Microbiol Immunol Infect. 38: 25–30.

Macnaughton, M R.; Hasony, HJ.; Madge, MH. and Reed, SE. (1981): Antibody to virus components in volunteers experimentally infected with human coronavirus 229E group viruses. Infect. & Immun 31: 845-849.

Marquardt, WW.; Snyder, DB. and Schlotthober, BA. (1981): Detection and quantification of antibodies to IBV by ELISA. Avian Dis 25: 713-722.

Mockett, APA. and Darbyshire, JH. (1981): Comparative studies with an ELISA for antibodies to avian IBV. Avian Pathol 10:      1-10.

Ruano, M.; El-Attrache, J. and Villegas, P.  (2000): A rapid-plate HA assay for the detection of IBV. Avian Dis 44: 99-104.

Seo, SH.; Wang, L.; Smith, R. and Collisson, EW. (1997): The carboxyl terminal 120-residue polypeptide of IBV nucleo capsid induces cytotoxic T lymphocytes and protects chickens from acute infection. J. Virol. 71: 7889–7894.

Shultze, B.; Cavanagh, D. and Herrler, G. (1992): Neuraminidase treatrnent of avianIBV reveals a HA activity that is dependent on sialic acid-containing receptors on erythrocyte. Virology 189: 792-794.

Snedecor, GW. and Cochran, WG. (1967): Statistical methods, 6th ed., Iowa State. Univ press, Ames., Iowa, USA.

Spaan, W.; Cavanagh, D. and Horzinek, MC. (1988):Coronaviruses: structure and genome expression J Gen Virol. 69: 2939–2952.

Villegas, PC. (1991):Lab. manual .avian virus diseases. pp 19 -20.Coll. Vet. Med. Athens, Georgia.

Villegas, PC. (2006): Lab. manual .avian virus diseases. pp 33, 37-38. Coll. Vet. Med. Athens, Georgia.

Worthington, KJ.; Currie, RJW. and Jones, RCs. (2008): A RT-PCR reaction survey of IBV genotype in Western Europe from 2002 to 2006. Avian path. 37: 247-257.

 

 

 

المقارنة بين اختبار منع التلازن الدموي واختبار الاليزا في الکشف عن الاستجابة المناعية بعد التحصين ضد فيروس الالتهاب الشعبي

 

هشام احمد عبد البديع محمد ، محمد عبد الله غنيمي هيکل

Email: heshambayoumie@yahoo.com

 

في دراستنا اردنا الوقوف علي قيمة اختبار منع التلازن الدموي عند  دراسة الاستجابة المناعية بعد التحصين ضد فيروسات مرض الالتهاب الشعبي و ذلک لقدرته التقريقية بين مختلف عترات الالتهاب الشعبي. حيث انه  بعد  معالجة عترات فيروس الالتهاب الشعبي  بإنزيم النيورامينيديز او الفوسفوليبيز يکتسب  فيروس الالتهاب الشعبي القدرة علي تلزين کرات الدم الحمراء. وبذلک يتيح اختبار منع التلازن الدموي  دراسة الاستجابة المناعية لکل عترة تحصين فيروسية علي حدة مما يتيح التدخل لوضع حلول عند اکتشاف فشل في التحصين لإي عترة تحصين سبق استعمالها وذلک في محاولة لخدمة صناعة الانتاج الداجني في تتبع  اي فشل في عملية  التحصين. وکذلک لما هو ثابت علمياً من ان اختبار الاليزا يعطي صورة واحدة اجمالية للمناعة ضد فيروس الالتهاب الشعبي مما يؤدي بالتبعية الي خلل في تقييم الاستجابة المناعية للتحصينات  ففي الوقت الذي يعطي اختبار الاليزا نتائج و قيم مناعية عالية تلاحظ لنا ان اختبار مانع التلازن يعطي قيم مناعية متدنية ضد عترة التحصين (mass-41 ) وضد العترة (4/91) وان هذا الاسلوب في تقييم المناعة يناسب ما هو معروف وثابت علمياً من وجود عترات کلاسيکية واخري مغايرة من فيروسات الالتهاب الشعبي وان التحصين بأيأً منهم لا يکفي لصد العدوي بالاخر و هذا مما يعقد استراتيجيات المقاومة لهذا المرض الفيروسي. وهذة الفلسفة الاخيرة من فکر المقاومة تعود بنا مرة اخري الي قيمة العودة الي استعمال اختبار منع التلازن الدموي اکثر من مرة علي حدة بإستعمال عترات فيروسية ضد تلک اللقاحات المغايرة المستعملة حقلياً (D-274, QX, 4/91, 1466 ) وعترات التحصين الکلاسيکية (Mass TYPE). تحسب درجة دقة الاختبار بعدد الايجابي من جملة العينات المختبرة وتحسب درجة حساسيته بعدد السلبي من جملة العينات المختبرة وقد وجدنا ان دقة اختبار الاليزا ودرجة حساسيته کانت 100% عند اختبار التخفيف 1/100 وکانت 80.96% و 95.5 علي التوالي عندما تم الاختبار عند تخفيف 1/1000 وقد کانت دقة الاختبار وحساسيته 80.91 % و 95% في اختبار مانع التلازن الدموي بإستعمال انتجين العترة الکلاسيکية (Mass-41) وکانا 73.91% و 62% في نفس الاختبار عند استعمال انتجين العترة المغايرة (4/91) هذه النتائج تظهر القدرة الانتقائية في اختبار منع التلازن الدموي وقدرته علي اظهار صورة مناعية ضد کل عترة فيروسية علي حدة مختلفة عن الاخري في حين اظهراختبار الاليزا صورة مناعية جيدة هي اجمالية في عمومها ولکنها لم تکن کاشفة لکل حالة مناعية خاصة بکل عترة فيروسية استخدمت في عملية التحصين الوقائي. هذه الصورة سوف تختلف ايضاً بالتبعية حال استخدام انتجينات اخري مثل (D-274 or 1466….etc.,) وهذا يثبت صحة وجهة النظر التي اردنا بحثها. کانت لنا ايضاً بعض المآخذ علي اختبار الاليزا عند استخدامه في دراسة الاجسام المناعية الاميه لتقنين مواعيد التحصين وقد ظهر لنا هذا عند دراسة العينة (S-20) فقد وجدنا ان تتر الاليزا کان (2018 ±  12051) بدرجة انحراف معياري (6384) عند التخفيف 1/100 وکانت النتائج (754 ± 2406) بدرجة انحراف معياري (2385) عند التخفيف 1/1000 وعند حساب اللوغاريتم الثنائي لهذة القيم عند التخفيف البادئ 1/10 کان المقابل ( 317. ±14.28) و(4.  ±14.56) وقد کان التتر المناعي للمناعة الامية بإستخدام اختبار منع التلازن الدموي (4. ± 4.5) بإنحراف معياري مقداره (5.) عند استعمال انتجين العترة الکلاسيکية وقد کان التتر المناعي (1.5± 2.4) بإنحراف معياري مقداره (1.5) عند استعمال انتجين العترة المغايرة (4/91) وبذلک نري ان اختبار الاليزا قد يؤدي الي خطأ في تحديد مواعيد التحصين.

 

 
REFERANSES
 
Alexander, DJ. And Chettle, N.J. (1977): Procedures for HA and HI for avian IBV.Avian Pathl. 6: 9-17.
Ammayappan, A.; Upadhyay, C.; Gelb, J Jr. and Vakharia, VN. (2008): Complete genomic sequence analysis of IBV Ark DPI strain and its evolution by recombination. Virol J. 5: 157.
Auvigne, V.; Gibaud, S.; Leger, L.; Malher, X.; Currie, R. and Riggi, A. (2013): A longitudinal study of incidence of IBV in France using strain-specific HI & cluster analysis.Revue Méd. Vét, 164: 417- 424.
Bochkov, YA.; Tosi, G.; Massi, P. and Drygin, VV. (2007): Phylogenetic analysis of partial S1 and N gene of IBV isolates from Italy revealed genetic diversity and recombination. Virus Genes. 35: 65–71.
Brugh, MA. Jr. (1978): A simple method for recording and analyzing serological data. Avian Dis.22: 362- 365.
Callison, SA.; Jackwood, MW. and Hilt, DA. (2001): Molecular characterization of IBV isolates foreign to the United States and comparison with USA isolates. Avian Dis. 45: 492–499.
Cavanagh, D. and Gelb, J. (2008): IBV. In diseases of poultry 12th ed. Editor Saif. Y.M.pp.        117-135.
Cook, JKA.; Orbell, SJ.; Woods, MA. and Huggins, MB. (1999): Breadth of protection of the respiratory tract provided by different live-attenuated infectious bronchitis vaccines against challenge with infectious bronchitis viruses of heterologous serotypes. Avian Pathol. 28: 477–485.
Darbyshire, JH. (1985): A clearance test to assess protection in chickens vaccinated against avian IBV. Avian Pathol. 14: 497–508.
De Wit, JJ. (2000): Detection of infectious bronchitis. Avian Pathology 29: 71, 93.
De Wit, JJ.; Mekkes, DR.; Kouwenhoven, B. and Verheijden, JH M. (1997):Sensitivity and specificity of serological tests for detection of IBV induced antibodies in broilers. Avian Pathol 26: 105-118.
De Wit, JJ.; Mekkes, DR.; Koch, G. and Westenbrink, F. (1998): Detection of specific Igm antibodies to IBV by an antibody capture ELISA. Avian Pathol 27: 2 155-160.
Dhinakar, RAJ G. and Jones, RC. (1997): Infectious bronchitis virus: immunopathogenesis of infection in the chicken. Avian Path. J. Of the W.V.P.A .26: 677‑706.
Gelb, JJ.; Weisman, Y.; Ladman, BS. and Meir, R. (2005): S1 gene characteristics and efficacy of vaccination against IBV field isolates from the USA and Israel (1996–2000). Avian Pathol. 34: 194–203.
Ignjatovic, J. and Galli, L. (1995): Immune responses to structural proteins of avian infectious bronchitis virus. Avian Pathol. 24: 313–332.
Ignjatovic, J.; Gould, G. and Sapats, S. (2006): Isolation of a variant IBV in Australia that further illustrates diversity among emerging strains. Arch Virol.151: 1567–1585.
Jackwood, MW. and De Wit, JJ. (2013): IBV.In: Dis. of Poult. 13th edition. Edit. David E. Swayne pp 139 -160.
Karaca, K. and Naqi, SN. (1993): A monoclonal antibody-based ELISA to detect serotype-specific IBV antibodies. Vet Microbiol 34: 249-257.
King, DJ. and Hopkins, SR. (1984): Rapid serotyping of IBV isolates with the HI. Avian Dis. 44: 325-335.
Kurian, A.; Neumann, EJ.; Hall, WF. and Marks, D. (2012):Effects of blood sample mishandling on ELISA results for infectious bronchitis virus, avian encephalomyelitis virus and chicken anaemia virus.The  Vet.  Journal 192: 378–381.
Lee, CW.; Brown, C.; Hilt, DA. and Jackwood, MW. (2004): Nephropathogenesis of chickens experimentally infected with various strains of IBV.J. Vet. Med. Sci. 66: 835–840.
Lee, EK.; Jeon, WJ.; Lee, YJ.; Jeong, OM.; Choi, JG.; Kwon, JH. and Choi, KS. (2008): Genetic diversity of avian infectious bronchitis virus isolates in Korea between 2003 and 2006. Avian Dis. 52: 332–337.
Lin, KY.; Wang, HC. and Wang, CH. (2005): Protective effect of vaccination in chicks with IBV against field virus challenge. J. Microbiol Immunol Infect. 38: 25–30.
Macnaughton, M R.; Hasony, HJ.; Madge, MH. and Reed, SE. (1981): Antibody to virus components in volunteers experimentally infected with human coronavirus 229E group viruses. Infect. & Immun 31: 845-849.
Marquardt, WW.; Snyder, DB. and Schlotthober, BA. (1981): Detection and quantification of antibodies to IBV by ELISA. Avian Dis 25: 713-722.
Mockett, APA. and Darbyshire, JH. (1981): Comparative studies with an ELISA for antibodies to avian IBV. Avian Pathol 10:      1-10.
Ruano, M.; El-Attrache, J. and Villegas, P.  (2000): A rapid-plate HA assay for the detection of IBV. Avian Dis 44: 99-104.
Seo, SH.; Wang, L.; Smith, R. and Collisson, EW. (1997): The carboxyl terminal 120-residue polypeptide of IBV nucleo capsid induces cytotoxic T lymphocytes and protects chickens from acute infection. J. Virol. 71: 7889–7894.
Shultze, B.; Cavanagh, D. and Herrler, G. (1992): Neuraminidase treatrnent of avianIBV reveals a HA activity that is dependent on sialic acid-containing receptors on erythrocyte. Virology 189: 792-794.
Snedecor, GW. and Cochran, WG. (1967): Statistical methods, 6th ed., Iowa State. Univ press, Ames., Iowa, USA.
Spaan, W.; Cavanagh, D. and Horzinek, MC. (1988):Coronaviruses: structure and genome expression J Gen Virol. 69: 2939–2952.
Villegas, PC. (1991):Lab. manual .avian virus diseases. pp 19 -20.Coll. Vet. Med. Athens, Georgia.
Villegas, PC. (2006): Lab. manual .avian virus diseases. pp 33, 37-38. Coll. Vet. Med. Athens, Georgia.
Worthington, KJ.; Currie, RJW. and Jones, RCs. (2008): A RT-PCR reaction survey of IBV genotype in Western Europe from 2002 to 2006. Avian path. 37: 247-257.