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正我国自1992年家禽中发生H9N2亚型禽流感以来,又先后发生H5和H7亚型禽流感流行,不仅造成严重经济损失,给养殖业带来灾难性打击,而且这些亚型的禽流感病毒可感染部分人群,引发严重的公共卫生事件。虽然我国从家禽中曾分离到很多种亚型的A型流感病毒,但就危害性而言最重要的是H5N1(H5NX)、H7N9和H9N2三个亚型。1 H9N2亚型禽流感流行特点和进化动态H9N2亚型禽流感是我国家禽中存在最广泛、传播最快的禽流感。 相似文献
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《中国家禽》2016,(1)
采用悬浮杀灭试验,考察戊二醛苯扎溴铵溶液对H9N2亚型禽流感病毒的灭活效果。将戊二醛苯扎溴铵溶液通过不同稀释倍数(1 250、2 500、5 000、10 000、20 000)、在不同作用时间(5、10 min)观察其对H9N2亚型禽流感病毒的灭活效果。结果显示,戊二醛苯扎溴铵溶液在10000倍稀释,与H9N2亚型禽流感病毒作用5 min或10 min,灭活率达99.90%以上;在20 000倍稀释,作用5 min或10 min,灭活率均小于99.90%。表明戊二醛苯扎溴铵溶液在10 000倍稀释与H9N2亚型禽流感病毒(20±1)℃水浴作用5 min,即可对H9N2亚型禽流感病毒达到很好的灭活效果。 相似文献
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为了监测鸡新城疫、传染性支气管炎、禽流感(H9亚型)三联灭活疫苗(LaSota株+M41株+SS/94株)对H9亚型禽流感病毒流行毒株的免疫保护效果,采用H9亚型禽流感病毒SS/94株及2009—2010年现地分离的3株H9亚型禽流感病毒对已免疫上述三联灭活苗的SPF鸡进行攻毒试验。结果显示,试验鸡以0.3 mL/只的剂量免疫三联灭活苗后21 d,其H9亚型禽流感病毒的HI抗体效价可达8~11log2,此抗体水平可抵抗2×106EID50的H9亚型禽流感病毒SS/94株、BLCN09株、WDZ09株、YT10株的攻击,攻毒保护率均达90%(9/10)以上。可见,以SS/94株作为禽流感疫苗抗原制备的三联灭活苗具有良好的免疫原性,能使免疫鸡抵抗2009—2010年期间现地分离的多株H9亚型禽流感病毒的攻击。 相似文献
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自我国首次报道在鸡群中分离到H9亚型禽流感病毒以来,我国多个省份均有该亚型禽流感发生的报道,尽管H9亚型禽流感病毒为低致病性病毒.在实验室内人工感染SPF鸡后一般不造成死亡,但在实践中,由于多种病原的协同作用,造成肉鸡呼吸道综合征以及死淘率升高,常造成严重的经济损失。 相似文献
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低致病性禽流感又叫致病性禽流感、非高致病性禽流感和温和型禽流感,是指某些致病性低的禽流感病毒毒株(如H9N2亚型)感染家禽引起的以低死亡率和轻度的呼吸道感染或产蛋率下降等临床症候群,其本身并不一定造成禽群的大规模死亡。但感染后往往造成禽群的免疫力下降,对各种病原的抵抗力降低,常常易发生并发或继发感染。 相似文献
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H9N2亚型禽流感疫苗在我国普遍使用,在强大免疫压力下,H9N2亚型禽流感病毒变异加快,现有商品化灭活苗无法完全保护免疫鸡免受H9N2亚型禽流感病毒流行株的感染。为此,本研究以从近期流行毒株中筛选出的一株H9N2亚型禽流感病毒A/Chicken/Shanghai/441/2009(H9N2)(简称为SH441)为种毒,制备灭活苗,进行了最小免疫剂量及抗体消长规律的初步研究。将制备的H9N2亚型禽流感灭活苗以0.01、0.02、0.04、0.05、0.08 mL/只的不同剂量,胸部肌肉途径免疫3周龄SPF鸡只,并于免疫后21天静脉感染SH441病毒,结果显示该疫苗最小免疫剂量为0.02 mL/只。以0.05 mL/只剂量免疫SPF鸡只,该疫苗能刺激SPF鸡只产生较高的HI抗体滴度,且在免疫后第5周达到峰值(12 Log2以上),随后稍有下降但保持相对稳定,且在免疫后29周时依然保持在7 Log2以上。这些结果为为该疫苗的进一步开发奠定了良好的基础。 相似文献
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为了检验鸡新城疫、传染性支气管炎、禽流感(H9亚型)三联灭活疫苗对H9亚型禽流感病毒流行毒株的免疫保护效果,将鸡新城疫、传染性支气管炎、禽流感(H9亚型)三联灭活疫苗免疫接种21日龄SPF鸡,免疫接种后3周采血测定AI(H9)HI抗体,并用2004年-2012年分离的8株H9亚型禽流感病毒对免疫接种鸡进行攻毒试验.结果显示,试验鸡免疫接种三联灭活苗后21 d,其H9 HI抗体效价可达11.88 log2,可抵抗8个不同H9亚型禽流感流行毒株的攻击,总攻毒保护率达92.50%(37/40).鸡新城疫-传染性支气管炎-禽流感(H9亚型)三联灭活疫苗中H9亚型禽流感毒株具有良好的免疫原性,能抵抗不同年代不同地区分离的H9亚型禽流感流行毒株的攻击. 相似文献
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H9亚型禽流感在我国家禽中广泛流行,给养禽业造成巨大经济损失的同时,也严重威胁着公共卫生安全。H9亚型禽流感病毒(avian influenza virus,AIV)具有高度遗传变异性,导致流行株和疫苗株之间抗原匹配性差,从而影响疫苗的临床保护效果,急需研发一种高效、具有交叉保护性的通用型H9亚型禽流感疫苗。马赛克疫苗是针对遗传多样性病原体设计,通过整合所有抗原序列获得一条抗原表位覆盖最广泛的嵌合蛋白,并制备疫苗。本研究参考mosaic疫苗设计原则,设计、优化并合成了一条H9亚型禽流感病毒的mosaic血凝素(hemagglutinin,HA)基因序列,采用反向遗传操作技术,以H1N1亚型流感病毒PR8株为骨架,以mosaic H9HA序列替换PR8株的HA片段,获得重组病毒rPR8-HAm/H9。将其制备为灭活疫苗并免疫SPF雏鸡,监测抗体水平、攻毒保护效果,评价其交叉保护效果。结果表明,重组病毒rPR8-HAm/H9灭活疫苗免疫SPF雏鸡,可诱导机体产生较高水平的HI抗体和中和抗体,可显著抑制攻毒后病毒的脱落,对H9N2 AIV JM0305株的攻毒保护率为80%。rPR8-HAm/H9灭活疫苗可以对异源H9N2 AIV JM0305株产生较好的交叉攻毒保护,为研发基于马赛克技术的禽流感通用疫苗提供了前期基础。 相似文献
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Despite the long-term vaccination programs implemented in China, H9N2 avian influenza viruses (AIVs) continue to persist in chicken populations, even in vaccinated flocks. We previously demonstrated that H9N2 AIV isolated from chickens in China also underwent antigenic drift and evolved into distinct antigenic groups (C, D and E). To understand whether antigenic drift of viruses away from the vaccine strain partially contributed to the circulation of H9N2 AIV in China, we evaluated the protective efficacy of a commercial vaccine against different antigenic groups of H9N2 AIV. Challenge experiments using vaccinated chickens indicated that the vaccine prevented shedding of antigenic group C viruses, but not those of the more recent groups D and E. Vaccinated chickens, even those with vaccine-induced HI titers of 1:1024, shed virus after being infected with A/chicken/Shandong/ZB/2007, a representative virus of antigenic group D. Genetic analysis showed that the representative viruses of antigenic groups D and E possessed greater numbers of amino acid substitutions in the hemagglutinin protein compared to the vaccine strain and the antigenic group C virus, and many of which were located in antigenic sites. Our results indicated that the persistence of H9N2 AIV in China might be due to incomplete vaccine protection, and that the avian influenza vaccine should be regularly evaluated and updated to maintain optimal protection. Furthermore, the avian influenza vaccination policy also needs to be re-assessed, and increased veterinary biosecurity on farms, rather than vaccine application alone, should be implemented to prevent and control avian influenza. 相似文献
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禽流感(avian influenza,AI)是由禽流感病毒(AIV)引起的一种禽类烈性综合征,威胁动物和人类公共健康,严重影响中国养禽业发展,接种疫苗一直是控制禽流感病毒传播最有效的手段。基于基因工程技术的不断发展,各种新型疫苗相继研发并投入使用。其中,禽流感DNA疫苗具有安全性高、制备方法简单、易于储藏和运输等优点,受到了广泛关注。常见的禽流感疫苗有HA DNA疫苗、NA DNA疫苗、M DNA疫苗、NP DNA疫苗等。禽流感DNA疫苗是将含有目的基因序列的重组质粒导入动物细胞,诱导动物机体产生体液和细胞免疫应答。为了提高禽流感DNA疫苗的免疫效果,国内外学者通过添加合适的佐剂、将目的基因导入理想质粒载体、对抗原序列优化,增强DNA疫苗的转染效率和基因表达水平,取得了一定的研究成果。自DNA疫苗开始研发至今,H1、H3、H5、H7、H9等众多亚型禽流感DNA疫苗逐步研发。2018年,由中国农业科学院哈尔滨兽医研究所研制的禽流感H5亚型DNA疫苗获得国家一类新兽药证书,是中国首个获得批准的禽流感DNA疫苗,极大地推动了DNA疫苗的发展。文章主要论述了禽流感DNA疫苗的载体构建、免疫机制、佐剂和载体选择以及疫苗研发等方面的研究进展和创新,并对其应用前景进行简要分析,旨在为科研工作者研制新型禽流感疫苗提供新的思路和参考。 相似文献
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Avian influenza (AI) is a kind of avian virulent syndrome caused by avian influenza virus (AIV),which threatens animal and human public health and seriously affects the development of poultry industry in China.Vaccination has always been the most effective means to control the spread of avian influenza virus.Based on the continuous development of genetic engineering technology,a variety of new vaccines have been developed and put into use.Among them,avian influenza DNA vaccine has many advantages,such as high safety,simple preparation,easy storage and transportation.Common HA DNA vaccine,NA DNA vaccine,M DNA vaccine,NP DNA vaccine.Avian influenza DNA vaccine introduces a recombinant plasmid containing the target gene sequence into animal cells to induce a humoral and cellular immune response.In order to improve the immune effect of avian influenza DNA vaccine,researchers at home and abroad have made some achievements in enhancing the transfection efficiency and gene expression level of DNA vaccine by adding appropriate adjuvants,introducing target genes into ideal plasmid vectors and optimizing antigen sequence.Since the development of DNA vaccines,many subtypes of avian influenza DNA vaccines,including H1,H3,H5,H7 and H9 subtypes,have been gradually developed.In 2018,the H5 subtype DNA vaccine developed by Harbin Veterinary Research Institute of The Chinese Academy of Agricultural Sciences obtained the National Class Ⅰ Veterinary Medicine certificate,which is the first DNA vaccine of avian influenza to be approved in China,greatly promoting the development of DNA vaccines.This review mainly discusses the development and innovation of avian influenza DNA vaccine in terms of vector construction,immune mechanism,adjuvant and vector selection,and vaccine research and development,and briefly analyzes its application prospect,in order to provide new ideas and references for researchers to develop new avian influenza vaccine. 相似文献
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To differentiate avian influenza virus (AIV)-infected chickens vs. chickens immunized with inactivated avian influenza virus, an enzyme-linked immunosorbent assay (ELISA) was developed using a recombinant nonstructural protein (NS1) as the diagnostic antigen, which was cloned from an AIV H9N2 subtype strain isolated during the avian influenza outbreak of 2003-04 and expressed in Escherichia coli. Antibodies to the AIV NS1 protein was only detected in the sera of chickens experimentally infected with AIV but not in the sera of chickens immunized with inactivated vaccine. This ELISA is useful for serological diagnosis to distinguish chickens infected with influenza viruses from those immunized with inactivated vaccine. 相似文献
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Song JM Lee YJ Jeong OM Kang HM Kim HR Kwon JH Kim JH Seong BL Kim YJ 《Veterinary microbiology》2008,130(3-4):268-276
The prevalence and continuous evolution of H9N2 avian influenza viruses in poultry have necessitated the use of vaccines in veterinary medicine. Because of the inadequate growth properties of some strains, additional steps are needed for producing vaccine seed virus. In this study, we generated three H9N2/PR8 reassortant viruses using a total cDNA plasmid-transfection system, as an alternative strategy for developing an avian influenza vaccine for animals. We investigated the vaccine potency of the reassortant viruses compared with the existing vaccine strain which was adapted by the 20th serial passages in embryonated eggs with A/Ck/Kor/01310/01 (H9N2). The H9N2/PR8 reassortant viruses, containing the internal genes of the high-yielding PR8 strain and the surface gene of the A/Ck/Kor/01310/01 strain, could be propagated in eggs to the same extent as existing vaccine strain without additional processing. Similar to vaccine strain, the H9N2/PR8 reassortant viruses induced hemagglutination-inhibiting antibodies in chickens and prevented virus shedding and replication in multiple organs in response to homologous infection. However, due to the continuing evolution and increasing biologic diversity of H9N2 influenza in Korea, the vaccine provided only partial protection against currently isolates. Taken together, our results suggest that the H9N2/PR8 reassortant virus can be used as a seed virus for avian influenza vaccines in poultry farm. Considering the constant genetic changes in H9 strains isolated in Korea, this reverse genetic system may offer a prompt and simple way to change the vaccine seed virus and mitigate the impact of unexpected influenza outbreaks. 相似文献
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Vaccines protect chickens against H5 highly pathogenic avian influenza in the face of genetic changes in field viruses over multiple years 总被引:7,自引:0,他引:7
Inactivated whole avian influenza (AI) virus vaccines, baculovirus-derived AI haemagglutinin vaccine and recombinant fowlpoxvirus-AI haemagglutinin vaccine were tested for the ability to protect chickens against multiple highly pathogenic (HP) H5 AI viruses. The vaccine and challenge viruses, or their haemagglutinin protein components, were obtained from field AI viruses of diverse backgrounds and included strains obtained from four continents, six host species, and isolated over a 38-year-period. The vaccines protected against clinical signs and death, and reduced the number of chickens shedding virus and the titre of the virus shed following a HP H5 AI virus challenge. Immunization with these vaccines should decrease AI virus shedding from the respiratory and digestive tracts of AI virus exposed chickens and reduce bird-to-bird transmission. Although most consistent reduction in respiratory shedding was afforded when vaccine was more similar to the challenge virus, the genetic drift of avian influenza virus did not interfere with general protection as has been reported for human influenza viruses. 相似文献
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2013年2月以来,华东地区被一场突如其来的"疫情"笼罩,后确诊为人感染H7N9禽流感病毒。由于被冠以“H7N9禽流感”,致使全国养禽业损失惨重。截至2013年上半年,受H7N9流感疫情影响,在短短3个月的时间内,养殖场户直接经济损失超过600亿元。最近,世界卫生组织(WHO)、世界动物卫生组织(OIE)和联合国粮农组织(FAO)等三家国际组织专家就“H7N9禽流感”名称会商,建议媒体使用“H7N9流感”或“H7N9病毒”的名称,这样更客观、准确。文章提出,对待类似情况,一定要本着科学、严谨的态度,不要因为人为的原因,造成不必要的损失,增加疾病控制的难度。 相似文献
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Raccoonpox virus (RCN) has been used as a recombinant vector against several mammalian pathogens but has not been tested in birds. The replication of RCN in chick embryo fibroblasts (CEFs) and chickens was studied with the use of highly pathogenic avian influenza virus H5N1 hemagglutinin (HA) as a model antigen and luciferase (luc) as a reporter gene. Although RCN replicated to low levels in CEFs, it efficiently expressed recombinant proteins and, in vivo, elicited anti-HA immunoglobulin yolk (IgY) antibody responses comparable to inactivated influenza virus. Biophotonic in vivo imaging of 1-wk-old chicks with RCN-luc showed strong expression of the luc reporter gene lasting up to 3 days postinfection. These studies demonstrate the potential of RCN as a vaccine vector for avian influenza and other poultry pathogens. 相似文献
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H9N2亚型禽流感病毒疫苗研究进展 总被引:2,自引:0,他引:2
H9N2亚型禽流感病毒在世界范围内广泛存在,给养禽业造成巨大的经济损失,并危害人类健康。流感病毒抗原易发生漂移和转换,使流感病毒的防控变得困难。疫苗接种是防控禽流感最有效的手段之一,全病毒灭活疫苗保护效果好,制备简单,是流感病毒常用的疫苗,但该疫苗局部副反应大,并伴随生物安全问题。随着分子生物学技术的发展,活载体疫苗、核酸疫苗、亚单位疫苗等新型疫苗的开发,给H9N2亚型禽流感病毒的防控提供了新的手段。新型疫苗除具有传统疫苗的保护效果外,在生物安全和普遍防控方面具有广泛的优势,是流感病毒疫苗发展的新方向。 相似文献