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为了评估野鸟在禽流感流行病学中的作用,于2004年4月-2005年6月间对上海地区捕捉到的63个品种的1 010只野鸟进行了血样和喉肛棉拭样品的采集.采用病毒分离试验和荧光RT-PCR试验对喉肛棉拭样品进行了病原学检测,结果均为阴性;采用HA和HI试验进行了禽流感血清抗体的检测,结果在15种野鸟的587份血样中检出了44份AIV阳性抗体,其中H1阳性数3份,阳性率为0.51%;H3阳性数4份,阳性率为0.68%;H5阳性数11份,阳性率为1.87%;H9阳性数26份,阳性率为4.43%. 相似文献
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《中国牛业科学》2016,(2)
[目的]为了掌握祁连山北麓中部地区牦牛常见病的感染情况。[方法]对祁连山北麓中部地区的牦牛常见病开展了血清学检测。共检测280份血清样品,分别检测了布病、口蹄疫、牛传染性鼻气管炎、弓形虫、牛副结核病的感染抗体。[结果]检出布病阳性样品3份,平均阳性率1.2%;检出口蹄疫病毒非结构蛋白3ABC抗体阳性样品31份,平均阳性率11.1%;检出牛传染性鼻气管炎阳性样品14份,平均阳性率5.0%;检出弓形虫抗体阳性样品87份,平均阳性率31.1%;检出牛副结核抗体阳性样品1份,平均阳性率0.4%。[结论]通过血清学检测,初步掌握了5种疫病的感染情况,为科学防控提供了科学依据。 相似文献
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为了更好地了解2022年湘阴县家禽中禽流感抗体水平和活禽批发市场禽流感病毒污染情况,通过春、秋两季免疫效果评估以及每个季度对两个活禽交易市场进行禽流感病毒专项监测,运用血凝抑制试验与实时荧光定量PCR的方法对血清及拭子样本进行禽流感病毒检测。结果显示:1200份禽血清中H5亚型AIV抗体整体合格率达到76.5%,H7亚型AIV抗体整体合格率达到78.8%;320份禽拭子和64份环境拭子中,H5亚型AIV阳性7份,阳性率1.8%,H7亚型AIV阳性数8份,阳性率2.0%。结果表明,家禽交易市场长期处于禽流感病毒污染状态。建议加强活禽市场管理,严格落实“1110”制度,确保禽类及产品的安全性和质量,降低禽流感病毒的传播速度和缩小传播范围。 相似文献
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为了解云南省玉溪市活禽交易市场禽流感病毒污染情况,2021年对该市8个县(市、区)活禽市场进行采样检测。全年共采集63场次1 455份棉拭子样品(禽咽喉/泄殖腔双拭子860份、环境拭子317份、运输工具拭子278份),采用荧光RT-PCR方法进行流感病毒A型、H5/H7/H9亚型流感病毒核酸检测。共检出A型流感病毒核酸阳性435份,未检测到H5和H7亚型病毒核酸阳性;除检出7份未分型阳性样品外,在44场次检出H9亚型病毒核酸阳性428份,场次阳性率为69.84%,样品阳性率为29.42%,其中活禽、环境、运输工具样品阳性率分别为32.56%、25.87%、23.74%,差异具有统计学意义(P<0.05)。一年四季均能检测到H9亚型病毒阳性,但3—6月份样品阳性率低于年均阳性率,1、2、7、10、12月样品阳性率明显高于其他月份,各月份间样品阳性率差异具有统计学意义(P<0.01)。各县(市、区)的场次阳性率存在差异(P<0.05),但样品阳性率差异无统计学意义(P>0.05)。结果表明:玉溪市活禽市场H5、H7亚型高致病性禽流感病毒的污染状况得到有效控制,但H9亚型禽流感病毒污染面依然广,污染率较高;不同月份间阳性率差异明显,但季节性差异缩小。结果提示,应继续加强活禽市场H9亚型禽流感病毒污染监测,同时强化活禽市场的检疫监管,严格执行消毒和休市制度,防止活禽市场禽流感病毒传入养殖环节。 相似文献
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本研究采集了新疆野鸟血清样品260份,进行了禽流感H1~H16亚型的血清学监测,结果显示,野鸭类血清样品2009年检出5个血清亚型,其中H8检出率高达15.38%,H13为9.62%;2010年检出11个血清亚型,H5亚型的阳性率最高,达14.29%;2011年检出12个血清亚型,其中H9检出率最高,达15.79%。不同品种野鸭的禽流感阳性检出率分析表明,绿头鸭禽流感抗体阳性率58.82%,赤麻鸭为68.66%,赤嘴浅鸭为34.09%,凤头浅鸭为44.44%。灰雁的血清样品检测结果表明,H13亚型的阳性率最高,为40.91%。1份天鹅血清样品检测出H13抗体阳性。对乌鸦、斑鸫、野鸽和红隼等野鸟血清样品检测,全部为阴性。本次在覆盖新疆边境的野生鸟类栖息地开展的禽流感血清学调查,掌握了新疆地区野生鸟类禽流感血清学监测数据,为新疆地区乃至全国的禽流感预警预测提供了科学依据。 相似文献
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《畜牧与兽医》2020,(11)
为摸清我国边境地区主要跨境动物疫病流行情况,本研究建立了重大跨境动物疫病风险监测预警的新模式—动物疫病远程诊断监测预警平台。使用该平台对云南瑞丽-缅甸边境、广西龙州-越南边境等地区规模场、种畜场、屠宰场以及散养户的1 328份猪血清、821份牛血清分别进行了猪瘟病毒抗体、口蹄疫病毒3ABC抗体、布鲁菌病抗体的血清学检测。共检出猪瘟抗体阳性血清705份,阳性率为53.1%;检出牛口蹄疫病毒3ABC抗体阳性血清143份,阳性率为17.4%;检出猪口蹄疫病毒3ABC抗体阳性血清127份,阳性率为9.6%;检出牛布鲁菌病抗体阳性血清17份,阳性率为2.1%。将上述检测结果实时上传至跨境动物疫病远程诊断监测预警溯源平台,实现了边境动物疫病的现场快速诊断检测与远程监测预警的新型检测模式。本研究所使用的快速诊断检测方法与国外主流诊断试剂盒的敏感性与特异性符合率较高。成功开发建立了跨境动物疫病风险监测预警新模式—远程诊断监测预警平台,探索了我国跨境地区场动物疫情监测新模式,为我国边境地区的动物疫病防控净化机制建设提供数据支持与技术支撑。 相似文献
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《养殖与饲料.饲料世界》2017,(12)
笔者对新沂市三新工程项目的 3个示范基地场及17乡镇90个养殖场(户),采集了1 835份猪血清及98份扁桃体,进行了伪狂犬病毒病原学、g E抗体和g B抗体的监测和分析。试验结果表明,共检出g E抗体阳性血清114份,阳性率为6.56%。其中3个示范场中,有2个示范基地场猪群中检出g E抗体阳性,其中1个场仅出现1头种公猪阳性,另1个场阳性率为8.06%;非示范基地825份血样中,共检出g E抗体阳性血清48份,抗体阳性率为5.81%。用PCR检测的98份样品,有3份检测出病毒核酸。从检测结果分析,新沂市辖区范围内生猪有伪狂犬野毒感染或因母本感染野毒导致母源抗体的存在。 相似文献
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编者按:尽管本文主要介绍人流感疫苗的研究情况,但其所涉及到的疫苗开发技术和思路对动物流感疫苗的开发具有极大的帮助和促进作用。故特此向广大读者推荐。 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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Scholtissek C 《Berliner und Münchener tier?rztliche Wochenschrift》2006,119(3-4):179-185
In this article the most important properties of influenza A viruses are described to understand influenza pandemics. There are at least three possibilities: (1) By reassortment between an avian and the prevailing human influenza A virus viruses with a new surface are created, against which no neutralizing antibodies are present in the human population. Such a virus can spread immediately worldwide. (2) Viruses, which have been present in the human population some time ago, reappear and infect the new generation, which has not been in contact with this virus before. (3) An avian influenza virus crosses the species barrier to humans and forms there a new stable lineage. In relation to pandemic planning, the first possibility can be more or less excluded, since the now-a-days human influenza A viruses have evolved so far away from their original source, the avian influenza viruses, that the formation of a well-growing and well-spreading reassortant is practically not possible anymore. Point two is a dangerous possibility, in that, e.g., a human H2N2 virus could reappear, which had disappeared in 1968 from the human population. The third possibility is at the moment the most dangerous situation, if, e.g., a highly neurotropic H5N1 virus from Southeast Asia crosses the species barrier to humans. An infection with such a pandemic virus presumably cannot be treated efficiently by antivirals. In such a situation only a rapid vaccination would be successful. In this respect in the last year important results have been obtained by using the reverse genetics. Meanwhile in about 50 countries there have been drawn up pandemic-preparedness plans. 相似文献