1.Development of oral cholera vaccine and its vaccination.
Chinese Journal of Preventive Medicine 2015;49(2):105-109
The application of the cholera vaccine is one of the cholera prevention and control strategies. Cholera vaccines stimulate mucosal immune to play the role of antibacteria and antitoxin. When the cholera toxin B subunit is added in the cholera vaccine, it could also defend against some diarrhea associated pathogens by cross-protection. Oral inactivated cholera vaccines are commercially available now. The oral live vaccine candidates are under development. The development of cholera vaccine is not only on the technical aspect, based on the situations of epidemic areas and population, cost, storage and transportation condition should also be considered. Though the argument on the use of cholera vaccine in epidemic areas and population in high risk existed previously, its vaccination has reached agreement now based on the clinical trials and evaluations during epidemic period.
Administration, Oral
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Cholera
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Cholera Toxin
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Cholera Vaccines
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Cross Protection
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Diarrhea
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Humans
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Vaccination
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Vaccines, Attenuated
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Vaccines, Inactivated
2.Study of immunogenicity after primary vaccination by different sequential program of inactivated poliovirus vaccine and oral poliovirus vaccine.
Li LU ; Xiao-mei LI ; Dong-lei LIU ; He-run ZHANG ; Zhu-jia-zi ZHANG ; Hai-hong WANG ; Fang LIU ; Zhao-qi NING ; Li-wen ZHANG ; Ping CHU ; Yan-tao XIE ; Ying XU ; Juan LI ; Xing-huo PANG ; Ying DENG
Chinese Journal of Preventive Medicine 2012;46(6):510-513
OBJECTIVETo evaluate immunogenicity after primary vaccination by different sequential program of inactivated poliovirus vaccine (IPV) and oral poliovirus vaccine (OPV).
METHODSChildren of 2 months old (60-89 days) selected in Beijing were assigned to 4 groups, 1 dose IPV plus 2 doses OPV (I-O-O, 122 children), 2 doses IPV plus 1 dose OPV(I-I-O, 103 children), 3 doses IPV (I-I-I, 114 children), and 3 doses OPV (O-O-O, 106 children), and were vaccinated at the age of 2, 3, 4 months. Polio neutralizing antibody titers against poliovirus types 1, 2, and 3 were tested and protective rates were calculated before the 1st dose, after the last dose, and after the 1st and 2nd dose of IPV.
RESULTSAfter the primary immunization, geometric mean titers (GMT) of polio neutralizing antibody titers against poliovirus types 1, 2, and 3 were 788.32, 738.42 and 631.17 in O-O-O group, 212.02, 262.30 and 537.52 in I-I-I group, 940.35, 929.72 and 940.35 in I-O-O group and 901.09, 1102.68 and 1110.12 in I-I-O group (F values were 47.71, 53.84, and 9.81 respectively, all P values<0.01). The protective rate of three types among each group was 98.1% (104/106)-100.0% and the difference was not statistically significant (P>0.05). After the 1(st) dose of IPV, the GMT were 18.88, 37.77, 24.64 and the protective rate was 82.6% (122/138)-96.4% (133/138); after the 2nd dose of IPV, GMT were 177.03, 168.25, 321.86 and the protective rate was 99.1% (108/109)-100.0% (109/109) in antibody types 1, 2 and 3, respectively.
CONCLUSIONGMT of polio neutralizing antibody titers against poliovirus is higher after vaccination by sequential program of IPV and OPV than that by IPV or OPV 3-doses program. High level of protective rate after 2 doses of IPV in I-I-O group may lead to better protection from vaccine associated paralytic poliomyelitis (VAPP). Sequential program of IPV and OPV can be used to maintain high level of herd immunity and to prevent VAPP, and the I-I-O sequential program should be the first choice.
Humans ; Immunization Schedule ; Infant ; Poliovirus Vaccine, Inactivated ; administration & dosage ; immunology ; Poliovirus Vaccine, Oral ; administration & dosage ; immunology ; Vaccines, Attenuated ; immunology
3.Safety of different sequential immunization schedules of inactivated poliovirus vaccine and oral poliovirus vaccine primary vaccination.
Zhu-jia-zi ZHANG ; Juan LI ; Hai-hong WANG ; Fang LIU ; Zhao-qi NING ; Ying XU ; Ping CHU ; Yan-tao XIE ; Xiao-mei LI ; Dong-lei LIU ; Li LU
Chinese Journal of Preventive Medicine 2013;47(10):910-915
OBJECTIVETo evaluate safety of different sequential immunization schedules of inactivated poliovirus vaccine (IPV) and oral poliovirus vaccine (OPV) primary vaccination.
METHODSInfants of 2 months old (60-89 days) selected in Beijing, were assigned to four groups, 1 dose IPV plus 2 doses OPV (I-O-O), 2 doses IPV plus 1 dose OPV(I-I-O), 3 doses IPV (I-I-I), and 3 doses OPV (O-O-O), and were vaccinated at the age of 2, 3, 4 months, from 2009 to 2011. The frequencies of systemic as well as local injection site reactions after every dose were recorded and calculated. A total of 553 infants were enrolled in the study and 89 infants were quit, 1492 diseases were observed.
RESULTSThe incidence of adverse events in I-O-O, I-I-O, I-I-I, O-O-O were 22.9% (94/410), 18.4% (60/327), 22.0% (78/354) and 17.7% (71/401) with no statistical differences (χ(2) = 4.84, P = 0.184). Dose 1 (22.7% (32/141)-35.3% (54/153) ) was more frequently than dose 2 and dose 3. No serious adverse events (SAE) were reported during the study. The incidence of systemic adverse reactions in I-O-O, I-I-O, I-I-I, O-O-O were 21.5% (88/410), 17.7% (58/327) , 20.1% (71/354) and 17.7% (71/401) with no statistical differences (χ(2) = 2.53, P = 0.472). Abnormal crying were the most frequency reactions (7.2% (29/401)-11.3% (37/327) ) in 4 groups. Rarely severe reactions were observed of abnormal crying, somnolence, irritability and mild or medium reactions occurred in other symptoms. Local adverse reactions such as injection site pain, scleroma and swelling were reported by 2.2% (5/229)-5.6% (22/393) ,0-0.9% (2/229) and 0-1.0% (4/393) in I-O-O,I-I-O and I-I-I, and most reactions were mild.
CONCLUSIONThree IPV immunization and IPV/OPV sequential immunization as well as three OPV immunization demonstrated safe.
Humans ; Immunization Schedule ; Infant ; Poliovirus Vaccine, Inactivated ; administration & dosage ; adverse effects ; Vaccines, Attenuated ; administration & dosage ; adverse effects
4.The study on the 0, 12 month vaccination schedule' of Healive inactivated hepatitis A vaccine in children.
Yin-hai REN ; Jiang-ting CHEN ; Wen-ting WU ; Xue-jie GONG ; Yu-cheng ZHANG ; Wei-hua XUE ; Yi-feng REN ; Lian-jun HAN ; Wen-xue KANG ; Sheng-ping LI ; Chong-bai LIU
Chinese Journal of Epidemiology 2003;24(11):1013-1015
OBJECTIVETo evaluate the safety, immunogenicity and fit dosage of Healive inactivated hepatitis A vaccine (HAV) in children.
METHODSA total of 85 susceptible aged 4 - 10 years with HAV seronegative children, had been enrolled from two adjacent villages in a county. The volunteers were randomized allocated into two groups and to receive a priming dose of 250 U/0.5 ml/dose or 500 U/1.0 ml/dose of Healive vaccine, produced by Sinovac Biotech Co, Ltd. A booster of the same dose was given at 12th month. Local and systemic side effects were examined and seroconversion rate as well as geometric mean titers of anti-HAV antibody were tested at 3-week, 12-month after the primary dose and at 1 month after the booster dose.
RESULTSThe vaccine was well tolerated in both groups. At 21 days after the primary dose, the seroconversion rates were 94.4%, 100.0% and geometric mean titers (GMT) were 195 mIU/ml and 370 mIU/ml in 250 U and 500 U groups respectively. At 12 months after the primary dose, the seroconversion rate of anti-HAV was 100.0%, and GMT raised to 361 mIU/ml, 456 mIU/ml (P > 0.05) respectively. One month after the booster dose, GMT raised to 14 893 mIU/ml, 21 696 mIU/ml.
CONCLUSIONGMT of the 0, 12 month schedule was higher than other schedule after the booster vaccination. The Healive inactivated vaccine can be used for emergency vaccination. The Healive inactivated vaccine produced by Sinovac Company Ltd was safe and highly immunogenic. Two hundred and fifty U/dose was considered appropriate for children.
Child ; Child, Preschool ; Dose-Response Relationship, Immunologic ; Drug Administration Schedule ; Hepatitis A ; immunology ; prevention & control ; Hepatitis A Antibodies ; analysis ; Hepatitis A Vaccines ; administration & dosage ; immunology ; Humans ; Vaccines, Inactivated ; administration & dosage ; immunology
5.Study on the strategy of Japanese encephalitis immunization using live attenuated vaccine combined with inactivated vaccine.
Fu-bao MA ; Li ZHENG ; Cheng BI ; Hong TAO ; Yong-lin ZHOU ; Jin-lin ZHANG ; Fen-yang TANG ; Ping XIE ; Chun-zao ZHENG ; Wei-bin PENG ; Ren-jie JIANG
Chinese Journal of Epidemiology 2003;24(2):113-115
OBJECTIVEUsing the advantages of Japanese encephalitis live attenuated and inactivated vaccine, to reduce the rate of immunization reaction and to increase the effect, we conducted a study on the strategy of immunization in Japanese encephalitis using live attenuated vaccine combined with inactivated vaccine.
METHODSObserving the safety and immune effects of different groups.
RESULTSData on side effect showed that the rate of moderate and severe systematic reactions of the group who were inoculated with combined vaccine was 0.73%, with local reaction 1.46% while the combined rate of moderate and severe systematic reaction of the group who were inoculated with inactivated vaccine was 2.8%. Under the detection of serum neutralizing antibody, the GMT rose from 1:1.05 - 1:3.35 before vaccination to 1:47.34 - 1:101.30 after vaccination in the different groups. Neutralizing antibody was detected in 97.67% of the combined group. There was a significant difference by comparing neutralizing antibody seroconversion rate of the combined group with the inactivated group (chi(2) = 3.89, P < 0.05), but no significant difference with attenuated group (chi(2) = 0.74, P > 0.05).
CONCLUSIONResults showed that in children who previously had been immunized with two doses of inactivated vaccine, the booster administration of live attenuated vaccine was both effective and safe.
Antibodies, Viral ; blood ; Child, Preschool ; Encephalitis Virus, Japanese ; immunology ; Humans ; Immunization ; Japanese Encephalitis Vaccines ; administration & dosage ; adverse effects ; immunology ; Vaccines, Attenuated ; immunology ; Vaccines, Inactivated ; immunology
6.Primary vaccination of infants against hepatitis B can be completed using a combined hexavalent diphtheria-tetanus-acellular pertussis-hepatitis B-inactivated poliomyelitis-Haemophilus influenzae type B vaccine.
Fong Seng LIM ; Htay-Htay HAN ; Jeanne-Marie JACQUET ; Hans L BOCK
Annals of the Academy of Medicine, Singapore 2007;36(10):801-806
INTRODUCTIONChildren in Singapore receive vaccination against hepatitis B virus (HBV) at 0, 1 and 5 or 6 months of age, and vaccination against pertussis, diphtheria, tetanus, and polio at 3, 4 and 5 months of age. Parents often choose to vaccinate with the combined acellular-pertussis-inactivated polio-Hib vaccine (DTPa-IPV/Hib). We investigated whether a combined hexavalent vaccine, DTPa-HBV-IPV/Hib, could replace the separate administration of DTPa-IPV/Hib and HBV for the final vaccination at 5 months of age (Trial DTPa-HBV-IPV-075).
MATERIALS AND METHODSIn an open study, 150 children were randomised to complete their vaccination schedule with DTPa-IPV/Hib + HBV or DTPa-HBV-IPV/Hib.
RESULTSOne month after the final vaccination, there was no difference between groups in seroprotection rates or antibody concentrations against HBV. Seroprotection rates against diphtheria, tetanus, Hib and polio, as well as vaccine response rates to pertussis antigens were also similar between groups. Local and general symptoms occurred at a similar rate after the third dose of either vaccine.
CONCLUSIONThe immunogenicity and reactogenicity of the hexavalent vaccine DTPa-HBV-IPV/Hib (Infanrix hexa, GSK) group is comparable to that of separately administered DTPa-IPV/Hib and HBV vaccines. Combined hexavalent vaccine, DTPa-HBV-IPV/Hib, could replace the separate administration of DTPa-IPV/Hib and HBV for vaccination at 5 months of age, thereby reducing the number of injections required.
Diphtheria ; immunology ; Diphtheria-Tetanus-Pertussis Vaccine ; Female ; Haemophilus Vaccines ; Haemophilus influenzae ; immunology ; Hepatitis B ; prevention & control ; Hepatitis B Antibodies ; blood ; Hepatitis B Vaccines ; administration & dosage ; Humans ; Immunization Schedule ; Infant ; Infant, Newborn ; Male ; Poliovirus Vaccine, Inactivated ; Singapore ; Tetanus ; immunology ; Vaccination ; Vaccines, Combined ; administration & dosage ; Vaccines, Inactivated
7.Protective efficacy of commercial inactivated Newcastle disease virus vaccines in chickens against a recent Korean epizootic strain.
Woo Jin JEON ; Eun Kyoung LEE ; Young Jeong LEE ; Ok Mi JEONG ; Yong Joo KIM ; Jun Hun KWON ; Kang Seuk CHOI
Journal of Veterinary Science 2008;9(3):295-300
Despite the intensive vaccination policy that has been put in place to control Newcastle disease virus (NDV), the recent emergence of NDV genotype VII strains in Korea has led to significant economic losses in the poultry industry. We ssessed the ability of inactivated, oil-emulsion vaccines derived from La Sota or Ulster 2C NDV strains to protect chickens from challenge with Kr-005/00, which is a recently isolated Korean epizootic genotype VII strain. Six-week-old SPF chickens were vaccinated once and challenged three weeks later via the eye drop/intranasal route. All vaccinated birds were fully protected from disease, regardless of the vaccine strains used. All vaccinated and challenged groups showed significant sero-conversion 14 days after challenge. However, some vaccinated birds, despite being protected from disease, shed the challenge virus from their oro-pharynx and cloaca, albeit at significantly lower titers than the unvaccinated challenged control birds. The virological, serological, and epidemiological significance of our observations with regard to NDV disease eradication is discussed.
Administration, Intranasal
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Animals
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Chickens
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Cloaca/virology
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Disease Outbreaks/prevention & control/*veterinary
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Korea
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Newcastle Disease/*immunology/prevention & control
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Newcastle disease virus/*immunology
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Ophthalmic Solutions
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Poultry Diseases/*immunology/prevention & control
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*Vaccines, Inactivated/administration & dosage
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Viral Vaccines/*administration & dosage
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Virus Shedding/drug effects
8.Immunogenicity and Safety of Trivalent Inactivated Influenza Vaccine: A Randomized, Double-Blind, Multi-Center, Phase 3 Clinical Trial in a Vaccine-Limited Country.
Joon Young SONG ; Hee Jin CHEONG ; Heung Jeong WOO ; Seong Heon WIE ; Jin Soo LEE ; Moon Hyun CHUNG ; Yang Ree KIM ; Sook In JUNG ; Kyung Hwa PARK ; Tae Hyong KIM ; Soo Taek UH ; Woo Joo KIM
Journal of Korean Medical Science 2011;26(2):191-195
Influenza vaccines are the primary method for controlling influenza and its complications. This study was conducted as a phase 3, randomized, double-blind, controlled, multi-center trial at seven university hospitals to evaluate the immunogenicity and safety of an inactivated, split, trivalent influenza vaccine (GC501, Green Cross Corporation, Yongin, Korea), which was newly manufactured in Korea in 2008. Between September 21 and 26, a total of 329 healthy subjects were recruited for the immunogenicity analysis, while 976 subjects were enrolled for the safety analysis. The GC501 vaccine met both FDA and EMEA criteria with > or = 80% of subjects achieving post-vaccination titers > or = 40 for all three subtypes, even in the elderly. The vaccine was well tolerated with only mild systemic and local adverse events. In summary, GC501 showed excellent immunogenicity and a good safety profile in both young adults and the elderly. The licensure of GC501 might be an important basis in preparation for the future influenza pandemic.
Adolescent
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Adult
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Aged
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Aged, 80 and over
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Double-Blind Method
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Humans
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Influenza Vaccines/administration & dosage/*adverse effects/*immunology
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Influenza, Human/*prevention & control
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Male
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Middle Aged
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Republic of Korea
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Vaccination
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Vaccines, Inactivated/administration & dosage/adverse effects/immunology
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Young Adult
9.Immunoprotective effect of inactivated coxsackievirus A16 vaccine in mice.
Xiang-Peng CHEN ; Xiao-Juan TAN ; Yong ZHANG ; Wen-Bo XU
Chinese Journal of Virology 2014;30(3):226-232
This study aims to construct inactivated coxsackievirus A16 (CVA16) vaccine and to investigate its protective effect in ICR mice. A clinical isolate of CVA16, 521-01T, was cultured in VERO cells, inactivated by formaldehyde, and purified by ultracentrifugation for vaccine preparation. Purity and other characteristics of the vaccine were determined by SDS-PAGE and Western blot. Female ICR mice were subcutaneously inoculated with inactivated CVA16 or Al(OH)3-absorbed CVA16, followed by booster immunization at the end of 2 and 4 weeks. CVA16-specific IgG titers in serum were determined by ELISA, and titers of neutralizing antibodies were determined by viral neutralization assay. The immunity of T lymphocytes was evaluated by IFN-gamma ELISPOT assay. The protective effect was evaluated by challenging the neonatal offspring (< 48 hours) of vaccinated female mice with 1 000 LD50 of CVA16 521-01T. The mortality rates of different groups were compared. The results showed that Al(OH)3 +CVA16 could induce high titers of specific IgG antibodies in ICR mice. After being boosted two times, the serum IgG antibody titer could reach up to 1 : 1 x 10(5) (P = 0.000), and neutralizing antibody titer was higher than 1 : 256. Additionally, more spot forming cells were induced in the immunized groups than in the negative controls. The maternal antibodies showed protective effect in 100% of the neonatal mice challenged with 1 000 LD50 of CVA16 521-01T. The inactivated CVA16 vaccine has ideal immunogenicity and immunoprotective effect. This research lays a foundation for the development and evaluation of CVA16 vaccines.
Animals
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Antibodies, Neutralizing
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immunology
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Antibodies, Viral
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immunology
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Enterovirus
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immunology
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Enterovirus Infections
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immunology
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prevention & control
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virology
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Female
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Humans
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Immunization
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Mice
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Mice, Inbred ICR
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T-Lymphocytes
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immunology
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virology
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Vaccines, Inactivated
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administration & dosage
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immunology
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Viral Vaccines
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administration & dosage
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immunology
10.Protection of chicken against very virulent IBDV provided by in ovo priming with DNA vaccine and boosting with killed vaccine and the adjuvant effects of plasmid-encoded chicken interleukin-2 and interferon-gamma.
Jeong Ho PARK ; Haan Woo SUNG ; Byung Il YOON ; Hyuk Moo KWON
Journal of Veterinary Science 2009;10(2):131-139
The aim of this study was to examine the efficacy of in ovo prime-boost vaccination against infectious bursal disease virus (IBDV) using a DNA vaccine to prime in ovo followed by a killed-vaccine boost post hatching. In addition, the adjuvant effects of plasmid-encoded chicken interleukin-2 and chicken interferon-gamma were tested in conjunction with the vaccine. A plasmid DNA vaccine (pcDNA-VP243) encoding the VP2, VP4, and VP3 proteins of the very virulent IBDV (vvIBDV) SH/92 strain was injected into the amniotic sac alone or in combination with a plasmid encoding chicken IL-2 (ChIL-2) or chicken IFN-gamma (ChIFN-gamma) at embryonation day 18, followed by an intramuscular injection of a commercial killed IBD vaccine at 1 week of age. The chickens were orally challenged with the vvIBDV SH/92 strain at 3 weeks of age and observed for 10 days. In ovo DNA immunization followed by a killed-vaccine boost provided significantly better immunity than the other options. No mortality was observed in this group after a challenge with the vvIBDV. The prime-boost strategy was moderately effective against bursal damage, which was measured by the bursa weight/body weight ratio, the presence of IBDV RNA, and the bursal lesion score. In ovo DNA vaccination with no boost did not provide sufficient immunity, and the addition of ChIL-2 or ChIFN-gamma did not enhance protective immunity. In the ConA-induced lymphocyte proliferation assay of peripheral blood lymphocyte collected 10 days post-challenge, there was greater proliferation responses in the DNA vaccine plus boost and DNA vaccine with ChIL-2 plus boost groups compared to the other groups. These findings suggest that priming with DNA vaccine and boosting with killed vaccine is an effective strategy for protecting chickens against vvIBDV.
Adjuvants, Immunologic/pharmacology
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Animals
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Antibodies, Viral/blood
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Birnaviridae Infections/immunology/prevention & control/*veterinary/virology
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Body Weight/immunology
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Bursa of Fabricius/immunology
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Chick Embryo
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*Chickens
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Histocytochemistry/veterinary
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Immunization/*veterinary
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Infectious bursal disease virus/genetics/*immunology
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Interferon-gamma/pharmacology
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Interleukin-2/pharmacology
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Organ Size/immunology
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Poultry Diseases/immunology/*prevention & control/virology
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RNA, Viral/chemistry/genetics
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Random Allocation
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Reverse Transcriptase Polymerase Chain Reaction/veterinary
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Specific Pathogen-Free Organisms
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Vaccines, DNA/*administration & dosage/immunology
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Vaccines, Inactivated/administration & dosage/immunology
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Viral Vaccines/*administration & dosage/immunology