Laboratory trials with inactivated vaccines against Escherichia coli (O2:K1) infection in fowls.

Laboratory trials were carried out with an O2:K1 vaccine prepared with either the Freund's complete or incomplete adjuvant. Both types of vaccine administered subcutaneously were highly effective against a challenge with the vaccine strain within three to four weeks after vaccination at two to three weeks of age. The complete adjuvant vaccine was more effective than the incomplete adjuvant vaccine when administered to chickens of an earlier age, and in the rate of development and duration of immunity. The efficacy of both vaccines was unimpaired by their incorporation with the Newcastle disease oil adjuvant (inactivated) vaccine (Newcadin). The use of an oil adjuvant vaccine was not found to affect the rate of growth adversely or to produce any other reaction prejudicial to its commerical application. The efficacy of the vaccines was unimpaired by their incorporation with Newcastle disease oil adjuvant (inactivated) vaccine (Newcadin) thus demonstrating the possibility of producing a combined Escherichia coli/Newcastle disease virus vaccine.     

Efficacy of an inactivated vaccine against hydropericardium syndrome in broilers

Field trials were used to assess the efficacy of an inactivated vaccine against hydropericardium syndrome in broiler chickens. A single vaccination at 10 to 12 days old was effective for the control of the syndrome; mortality in the vaccinated birds was 0.52 per cent compared with 5.34 per cent in unvaccinated birds kept at the same premises. Vaccination was also effective when carried out in the face of an outbreak; mortality in the vaccinated infected birds was 2.33 per cent compared with 10.27 per cent in unvaccinated infected birds. The data indicate that a formalinised vaccine prepared from the liver of experimentally infected birds could be used for the control of hydropericardium syndrome.     

Immunization of mice and calves against Salmonella dublin with attenuated live and inactivated vaccines.

Previous findings, viz. that mice can be successfully immunized against infection with Salmonella dublin with either live or inactivated vaccine, were confirmed. Immunity lasted for at least 12 weeks in mice which had been immunized with inactivated alum-precipitated vaccine. The immunogenicity of inactivated vaccine gradually decreased on storage at 4 degrees C, but this was only detectable if a single injection was used for immunization: 2 injections virtually eliminated this phenomenon. The immunogenicity of live vaccine in mice was not enhanced by levamizole or the simultaneous injection of inactivated organisms. Both live and inactivated vaccines provided immunity in calves. A single injection of lyophilized vaccine, prepared from live rough Salmonella dublin strain (HB 1/17),protected 3 out of 6 calves, while 2 injections of a formalin-inactivated, alum-precipated vaccine, containing 1% packed cells of S. dublin strain 2652 V, protected 5 out of 6 calves against intraduodenal challenge with 2 x 10(9), S. dublin strain 2652 V. Two calves which had been immunized with an inactivated oil adjuvant vaccine were also solidly immune to this challenge. Serum antibody response in calves was poor when measured by the tube agglutination and the haemagglutination tests. Similarly, the sera had only marginal protective values when tested by means of a passive protection test in mice. Antibody titres alone are not a valid measure therefore, for the immune status of immunized animals.     

Inactivated vaccine for parrot herpesvirus infections (Pacheco's disease)

Four tests of an inactivated emulsified vaccine against a herpesvirus infection (Pacheco's disease) in bodgerigars demonstrated that an effective vaccine could be produced with concentrated virus. Virus was propagated in chicken kidney cells, and cells and fluid were harvested 3 to 5 days after inoculation and sonicated. The virus was concentrated 100 x by centrifugation to produce a multiple emulsion vaccine that was protective against IM challenge exposure with live virus. The serologic response after vaccination was negligible, and many survivors to virus challenge exposure did not show a positive titer.     

Protection against feline leukemia virus infection by use of an inactivated virus vaccine.

The protective immunity induced by 3 experimental FeLV vaccines were evaluated: Prototype inactivated FeLV vaccine developed from a molecularly cloned FeLV isolate (FeLV-FAIDS-61E-A); a mixture of immunodominant synthetic peptides corresponding to regions of the FeLV-Gardner-Arnstein-B (FeLV-GA-B) envelope proteins; and an adjuvant-disrupted but non-activated virus prepared from a non-cloned FeLV field isolate comprised of subgroup A and B viruses (FeLV-05821-AB). Included as controls were parallel groups of cats inoculated with adjuvants alone or with an established commercial FeLV vaccine. After each inoculation and after virulent virus challenge exposure, sera from all cats were assayed for ELISA-reactive antibody against purified FeLV, FeLV neutralizing (VN) antibody, and FeLV antigenemia/viremia--viral p27 antigen in serum and within circulating leukocytes. Immunity was challenged by oral/nasal exposure of vaccinated and control cats with FeLV-FAIDS-61E-A or FeLV-05821-AB, an infective, noncloned, tissue-origin, FeLV field isolate containing subgroup-A and -B viruses. Vaccine-induced immunity was assessed by comparing the postchallenge-exposure incidence of persistent viremia and the pre- and postchallenge exposure titers of VN and ELISA antibody in cats of the control and vaccine groups. The percentage of cats, that resisted development of persistent viremia after FeLV challenge exposure and the preventable fraction (PF) for the vaccine groups (which adjusts for the severity of the challenge and the degree of innate resistance in the controls) were as follows: adjuvant controls, 26%; FeLV-FAIDS-61E-A inactivated virus vaccine, 95% (PF = 93.2%); FeLV-GA-B peptide vaccine, 5% (-28.4%); FeLV-05821-AB noninactivated vaccine, 67% (55.4%); and commercial FeLV vaccine, 35% (12.2%). The prechallenge exposure mean VN antibody titer for each group was: less than 1:8 in the adjuvant controls; 1:43 in the FeLV-FAIDS-61E-A-vaccinated cats; less than 1:8 in the peptide-vaccinated cats; 1:38 in the noninactivated virus-vaccinated cats group; and 1:12 in the cats vaccinated with the commercial vaccine. Thus, induction of VN antibody in the vaccinated cats, although modest, appeared to be correlated with induction of protective immunity as defined by resistance to FeLV challenge exposure. Results of these studies indicate that inoculation of cats with an experimental inactivated virus vaccine prepared from a molecularly cloned FeLV isolate was most effective in stimulating protective immunity against heterologous and homologous FeLV challenge exposure.     

Potency of an experimental DNA vaccine against Aujeszky's disease in pigs

Intradermal vaccination with plasmid DNA encoding envelope glycoprotein C (gC) of pseudorabies virus (PrV) conferred protection of pigs against Aujeszky's disease when challenged with strain 75V19, but proved to be inadequate for protection against the highly virulent strain NIA-3. To improve the performance of the DNA vaccine, animals were vaccinated intradermally with a combination of plasmids expressing PrV glycoproteins gB, gC, gD, or gE under control of the major immediate-early promotor/enhancer of human cytomegalovirus. 12.5 microg per plasmid were used per immunization of 5-week old piglets which were injected three times at biweekly intervals. Five out of six animals survived a lethal challenge with strain NIA-3 without exhibiting central nervous signs, whereas all the control animals succumbed to the disease. This result shows the increased protection afforded by administration of the plasmid mixture over vaccination with a gC expressing plasmid alone. A comparative trial was performed using commercially available inactivated and modified-live vaccines and a mixture of plasmids expressing gB, gC, and gD. gE was omitted to conform with current eradication strategies based on gE-deleted vaccines. All six animals vaccinated with the live vaccine survived the lethal NIA-3 challenge without showing severe clinical signs. In contrast, five of six animals immunized with the inactivated vaccine died, as did two non-vaccinated controls. In this test, three of six animals vaccinated with the DNA vaccine survived without severe clinical signs, whereas three succumbed to the disease. Comparing weight reduction and virus excretion, the DNA vaccine also ranged between the inactivated and modified-live vaccines. Thus, administration of DNA constructs expressing different PrV glycoproteins was superior to an adjuvanted inactivated vaccine but less effective than an attenuated live vaccine in protection of pigs against PrV infection. Our data suggest a potential use of DNA vaccination in circumstances which do not allow administration of live attenuated vaccines.     

Failure of protection and enhanced pneumonia with a US H1N2 swine influenza virus in pigs vaccinated with an inactivated classical swine H1N1 vaccine

Two US swine influenza virus (SIV) isolates, A/Swine/Iowa/15/1930 H1N1 (IA30) and A/Swine/Minnesota/00194/2003 H1N2 (MN03), were evaluated in an in vivo vaccination and challenge model. Inactivated vaccines were prepared from each isolate and used to immunize conventional pigs, followed by challenge with homologous or heterologous virus. Both inactivated vaccines provided complete protection against homologous challenge. However, the IA30 vaccine failed to protect against the heterologous MN03 challenge. Three of the nine pigs in this group had substantially greater percentages of lung lesions, suggesting the vaccine potentiated the pneumonia. In contrast, priming with live IA30 virus provided protection from nasal shedding and virus replication in the lung in MN03 challenged pigs. These data indicate that divergent viruses that did not cross-react serologically did not provide complete cross-protection when used in inactivated vaccines against heterologous challenge and may have enhanced disease. In addition, live virus infection conferred protection against heterologous challenge.     

Protection of chickens after live and inactivated virus vaccination against challenge with nephropathogenic infectious bronchitis virus PA/Wolgemuth/98

Protection provided by live and inactivated virus vaccination against challenge with the virulent nephropathogenic infectious bronchitis virus (NIBV) strain PA/Wolgemuth/98 was assessed. Vaccinations with combinations of live attenuated strains Massachusetts (Mass) + Connecticut (Conn) or Mass + Arkansas (Ark) were given by eyedrop to 2-wk-old specific-pathogen-free leghorn chickens. After live infectious bronchitis virus (IBV) vaccination, some chickens at 6 wk of age received an injection of either an oil emulsion vaccine containing inactivated IBV strains Mass + Ark or an autogenous vaccine prepared from NIBV PA/Wolgemuth/98. Challenge with PA/Wolgemuth/98 was given via eyedrop at 10 wk of age. Serum IBV enzyme-linked immunosorbent assay antibody geometric mean titers (GMTs) after vaccination with the combinations of live attenuated strains were low, ranging from 184 to 1,354, prior to NIBV challenge at 10 wk of age. Both inactivated vaccines induced an anamnestic response of similar magnitudes with serum GMTs of 6,232-12,241. Assessment of protection following NIBV challenge was based on several criteria virus reisolation from trachea and kidney and renal microscopic pathology and IBV-specific antigen immunohistochemistry (IHC). Live attenuated virus vaccination alone with combinations of strains Mass + Conn or Mass + Ark did not protect the respiratory tract and kidney of chickens after PA/Wolgemuth/98 challenge. Chickens given a live combination vaccination of Mass + Conn and boosted with an inactivated Mass + Ark vaccine were also susceptible to NIBV challenge on the basis of virus isolation from trachea and kidney butshowed protection on the basis of renal microscopic pathology and IHC. Live IBV-primed chickens vaccinated with an autogenous inactivated PA/Wolgemuth/98 vaccine had the highest protection against homologous virulent NIBV challenge on the basis of virus isolation.     

Testing the protective effectiveness of avirulent vaccines against trichophytosis in cattle

The protective action of live avirulent vaccine against bovine trichophytosis, produced by the Bioveta National Corporation at Ivanovice na Hané, was very good and fully comparable with the earlier vaccine produced from the virulent live culture of Trichophyton verrucosum. Experimental challenge with a massive dose of a virulent strain of T. verrucosum produced only minor surface dermal changes in the calves vaccinated with these vaccines, but these changes spontaneously disappeared in a short time. In the control non-vaccinated calves, large and deep lesions were induced by the challenge, spreading to the neighbouring tissues. Compared with both live biopreparations, the protective effect of inactivated vaccine prepared by the irradiation of virulent vaccine with Co60 was much lower.     

An inactivated parainfluenza virus type 3 vaccine: the influence of vaccination regime on the response of calves and their subsequent resistance to challenge.

Calves maintained in insolated pens were vaccinated with an inactivated parainfluenza virus type (3) (pi3) vaccine usingparenteral and local route singly and in combination. The calves were subsequently monitored for serum antibody response and challenged intranasally with live virus to assess the protection derived from vaccination. Calves receiving one subcutaneous dose of vaccine in oil adjuvant produced a marked antibody response and were partially protected against challenge. Those receiving two successive subcutaneous doses produced a much greater antiboyd response and were completely protected against challenge. One intranasal dose of aqueous vaccine failed elicit a significant serum antibody response or protection against challenge. However, there was some evidence that intranasal vaccination following a single subcutaneous vaccination produced more effective immunity than one subcutaneous dose alone. Thus a vaccination regime was established which protected calves against experimental challenge and which could thefore be used in the field to assess the role of Pi3 virus in calf respiratory disease.     

Evaluation in swine of a subunit vaccine against pseudorabies

A subunit vaccine against pseudorabies virus (PRV) was prepared by treating a mixture of pelleted virions and infected cells with the nonionic detergent Nonidet P-40 and emulsifying the extracted proteins incomplete Freund's adjuvant. Three 7-week-old pigs without antibodies against PRV were given 2 IM doses of this vaccine 3 weeks apart. Thirty days after the 2nd vaccination, 10(6) median tissue culture infective doses (TCID50) of a virulent strain of PRV were administered intranasally. Tonsillar and nasal swabs were collected daily between 2 and 10 days after challenge exposure. The pigs vaccinated with the subunit vaccine were not found to shed virulent PRV. Two groups of five 7-week-old pigs vaccinated with commercially available vaccines, either live-modified or inactivated virus, and subsequently exposed to 10(6) TCID50 of virulent PRV, shed virulent virus for up to 8 days. The subunit vaccine induced significantly higher virus-neutralizing antibody titers than either the live-modified or inactivated virus vaccine.     

Vaccination of day-old broiler chicks against Newcastle disease and infectious bursal disease using commercial live and/or inactivated vaccines

Day-old broilers were administered live and/or inactivated vaccines to assess vaccine efficacy against challenge with Newcastle disease (ND) and infectious bursal disease (IBD). Chicks were from commercial breeder pullets vaccinated against ND and IBD using several live vaccine primers followed by an inactivated ND-IBD vaccine at 18 weeks. The most efficacious initial ND-IBD vaccination program was live ND virus by eye drop and live IBD vaccine injected subcutaneously (SQ) followed 2 hours later with inactivated ND-IBD vaccine SQ. The next two most efficacious programs were live vaccine alone and the inactivated vaccine only. Inactivated vaccine given SQ had no adverse effect on live IBD vaccine given 2 hours earlier in a similar site. Administration of inactivated vaccine by vent was not as efficacious as administration SQ. A booster of a second live ND-IBD vaccine drinking water at 18 days significantly increased levels of circulating antibody, regardless of the initial vaccination program.     

Preparation and evaluation of inactivated avian Metapneumovirus vaccine from recently isolated Egyptian strain

Inactivated avian Metapneumovirus (aMPV) or turkey rhinotracheitis (TRT) virus vaccine was prepared from an Egyptian strain (Giza TRT-4). The virus was propagated in Vero cells and inactivated by binary ethyleneimine. The inactivated virus solution was tested for its sterility, purity, and safety. Then, it was mixed withNigella sativa oil as nonspecific immune-stimulant adjuvant. Physical characterization of oil prepared vaccine like viscosity and emulsion stability was investigated. An experiment was designed to evaluate the locally prepared aMPV vaccine in a comparison to commercial vaccines either inactivated or live attenuated. The obtained results showed that the locally prepared aMPV vaccine gave significantly higher humoral immune response when measured by ELISA and significantly higher cell mediated immunity by evaluating phagocytic activity of inoculated turkey poults with higher protection rate reached up to 100% after challenge with wild-type virus.     

A:L1型鸭源多杀性巴氏杆菌灭活疫苗制备及免疫效力研究

【目的】制备鸭多杀性巴氏杆菌灭活疫苗,有效控制贵州省鸭多杀性巴氏杆菌发生和流行。【方法】以实验室分离保存的A:L1型多杀性巴氏杆菌地方流行株为菌种,通过涂板法测定该菌株生长曲线,并采用改良寇氏法计算该菌株对鸭的半数致死量(median lethal dose, LD₅₀),将该菌培养至终浓度为1×10¹⁰ CFU/mL后分别制备白油佐剂灭活疫苗和卡波姆佐剂灭活疫苗,经疫苗质量检验后进行免疫雏鸭试验;通过攻毒保护试验评价比较两种疫苗的保护率,并对攻毒试验鸭肝脏、肺脏、脾脏进行病理组织学观察。【结果】A:L1型多杀性巴氏杆菌疫苗株培养至18 h到达峰值,活菌数可达1.0×10¹⁰ CFU/mL;LD₅₀为5 CFU;制备的两种疫苗安全性良好;攻毒保护试验结果显示,一免后卡波姆佐剂灭活疫苗免疫保护率可达62.5%,高于白油佐剂灭活疫苗(50.0%)及商品灭活疫苗(50.0%)。二免后卡波姆佐剂灭活疫苗优势更为明显,免疫保护率可达87.5%,高于白油佐剂灭活疫苗(75.0%)及商品灭活疫苗(62.5%)。病...     

Experiments on the preparations and testing of associated vaccine against foot and mouth disease and vesicular disease in swine.

Tests for associated immunization of swine against Foot and Mouth Disease (FMD) and Vesicular Disease (SVD) of swine were carried out. As a result of this investigation, it was established that the prepared and tested inactivated oil vaccine is harmless and immunogenic in sensitive animals. In investigating the course of immunity, the presence of antibody against both antigens was demonstrated in vaccinated animals. All once-vaccinated animals were defended against the virus of SVD during challenge, and 75% of them were defended against FMD. After revaccination, all immunized swine were defended against infection with both viruses. The question of the quality of the associated vaccine and the possibilities of its massive use in industrial swine rearing was discussed.     

雉鸡结核病疫苗研制及免疫试验

利用从患结核病雉鸡分离到的 5株禽型结核分枝杆菌研制出预防雉鸡结核病的禽型结核分枝杆菌灭活疫苗和卡介苗与灭活苗的混合疫苗。试验证明 ,该疫苗安全可靠 ,免疫效果良好。雉鸡血清中抗体可维持 8个月以上 ,抗自然感染保护率为 86 7% ,攻毒试验灭活苗保护率为 77 8% ,卡介苗与灭活苗的混合苗保护率为 83 3% ,免疫期 6个月。     

Vaccination of cats against feline immunodeficiency virus (FIV): a matter of challenge.

So far, most apparently successful immunodeficiency virus vaccines have only been tested against challenge with cell culture-adapted virus. However, even live priming of cats with feline herpesvirus (FHV) vectors expressing the FIV gag and env gene followed by inactivated booster vaccination with fixed FIX infected cell vaccine proved non-protective against infection with a primary FIV isolate. An effective FIV vaccine for field applications therefore is still not underway.     

禽流感（H9亚型）油乳剂灭活疫苗的研究

将H9亚型禽流感病毒尿囊液，经甲醛灭活，以矿物油为佐剂制成油乳剂灭活疫苗，疫苗物理性状良好，接种鸡无不良反应，接种疫苗后14d，食流感病毒HIGMT（Log2)为7.7-7.8，21d为8.9-9.3，于接种疫苗后14、21、30、60d，攻击同型禽流感病毒，接种疫苗鸡全部获得保护，现地实验取得了良好地免疫效果。证明制备的油乳剂灭活疫苗安全，免疫原性良好。     

PEG对嗜水气单胞菌疫苗制备与免疫效果影响的研究

为评价聚乙二醇(PEG)作为超声介质及疫苗佐剂对嗜水气单胞菌疫苗免疫效果的影响,本研究将该疫苗与常规疫苗分别经腹腔注射免疫接种锦鲤成鱼,检测血细胞吞噬百分率、吞噬指数、抗菌活力、抗体效价及免疫保护力等指标,评价疫苗效果.结果表明PEG6000作为佐剂制备的疫苗,其各指标均高于对照组及其他试验组.PEG6000疫苗免疫保护力达到77.8％,高于常规灭活疫苗22.2％,表明PEG6000作为佐剂制备的疫苗效果最好.     

Efficacy of bovine herpesvirus-1 inactivated vaccine against abortion and stillbirth in pregnant heifers

OBJECTIVE: To evaluate the efficacy of an inactivated bovine herpesvirus-1 (BHV-1) vaccine to protect against BHV-1 challenge-induced abortion and stillbirth. DESIGN: Prospective study. ANIMALS: 35 beef heifers. PROCEDURES: Before breeding, heifers were vaccinated with a commercially available BHV-1 inactivated vaccine SC or IM. The estrous cycle was then synchronized, and heifers were artificially inseminated 30 to 60 days after vaccination. Heifers (n = 21) were challenge inoculated IV at approximately 180 days of gestation with virulent BHV-1. Fourteen control heifers were not vaccinated. Clinical signs of BHV-1 infection were monitored for 10 days following challenge; serologic status and occurrence of abortion or stillbirth were evaluated until time of calving. RESULTS: 18 of 21 (85.7%) heifers that received vaccine were protected from abortion following challenge, whereas all 14 control heifers aborted. CONCLUSIONS AND CLINICAL RELEVANCE: Results indicated that an inactivated BHV-1 vaccine can protect against abortion resulting from a substantial challenge infection, with efficacy similar to that of modified-live BHV-1 vaccines.