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1.
Powder and particle-mediated approaches for delivery of DNA and protein vaccines into the epidermis 总被引:1,自引:0,他引:1
Dean HJ Fuller D Osorio JE 《Comparative immunology, microbiology and infectious diseases》2003,26(5-6):373-388
The epidermis of the skin is both a sensitive immune organ and a practical target site for vaccine administration. However, administration of vaccines into the epidermis is difficult to achieve using conventional vaccine delivery methods employing a needle and syringe. A needle-free vaccine delivery system has been developed that efficiently delivers powdered or particulate DNA and protein vaccines into the epidermal tissue. The delivery system can be used to directly transfect antigen presenting cells (APCs) by formulating DNA or protein vaccines onto gold particles (particle-mediated immunization). Antigen can be directly presented to the immune system by the transfected APCs. Antigen can also be expressed and secreted by transfected keratinocytes and picked up by resident APCs through the exogenous antigen presentation pathway. Alternatively, protein antigens can be formulated into a powder and delivered into the extracellular environment where they are picked up by APCs (epidermal powder immunization). Using any of these formulations, epidermal immunization offers the advantage of efficiently delivering vaccines into the APC-rich epidermis. Recent studies demonstrate that epidermal vaccine delivery induces humoral, cellular, and protective immune responses against infectious diseases in both laboratory animals and man. 相似文献
2.
Babiuk LA 《Veterinary journal (London, England : 1997)》2002,164(3):188-201
Conventional vaccines have been used for some 200 years, primarily to control infectious diseases. It is envisaged that such vaccines will continue to be used and new ones developed using conventional technology. However, in addition to conventional vaccines, novel approaches using biotechnology are already in use and many more are in various stages of development. These novel vaccines are not only being used to control infectious diseases, but also to improve productivity of livestock by modulating hormones, for gender selection, as well as in controlling ectoparasites. The recent developments in vaccination technology in all of these areas are described. 相似文献
3.
禽类DNA疫苗研究进展 总被引:2,自引:0,他引:2
新型疫苗的研究对于禽类传染病的防制意义重大。传统疫苗是基于抗原刺激机体产生特异性抗体的原理,它们大多数激发机体的体液免疫,很难启动细胞免疫。脱氧核糖核酸(DNA)疫苗作为第3代疫苗,具备传统疫苗和其它基因工程苗不可比拟的优点,能够诱导全方位的免疫反应且使用更安全更方便,DNA疫苗是将外源基因与真核质粒重组后直接导入细胞内,使外源基因在宿主细胞内表达合成保护性抗原蛋白。这是模拟病毒自然感染提呈过程,既能产生细胞免疫,又能产生体液免疫。文章对DNA疫苗在禽类应用的可行性和应用研究新进展作了综述。 相似文献
4.
新型猪瘟疫苗的研究进展 总被引:1,自引:1,他引:0
猪瘟是危害猪健康的重要传染病之一,具有急性、热性和高度接触性等特性,给世界养猪业造成了巨大的经济损失。目前,传统疫苗接种仍是预防猪瘟的主要手段,虽然传统疫苗(如C株)在防控猪瘟方面发挥着巨大的作用,但也存在一些缺陷,如无法区分野毒感染和疫苗免疫动物,猪瘟免疫失败时有发生等。因此,研制新型猪瘟疫苗具有重要意义。随着分子生物学技术与重组DNA技术的不断发展及基因工程疫苗研究的不断深入,亚单位疫苗、核酸疫苗、活载体重组疫苗、基因缺失疫苗、全长感染性cDNA标记疫苗和合成肽疫苗6种新型猪瘟疫苗被相继开发。与传统疫苗相比,新型疫苗拥有廉价、安全、高效、易于运输与保存、能区分野毒感染和疫苗免疫等优点。作者对6种新型猪瘟疫苗的研究进展作一综述,以期为猪瘟的防控提供参考。 相似文献
5.
Liu JJ Cepica A 《The Canadian veterinary journal. La revue veterinaire canadienne》1990,31(3):181-189
Numerous conventional vaccines for animal use are currently available, and many of these vaccines have been instrumental in the control of infectious diseases of major economic importance. A vaccine has even been instrumental in global eradication of smallpox, an important human disease. However, many of the current vaccines are deficient in efficiency, potency, or safety. It has been recognized that the conventional methodologies are a limitation to further vaccine development. Introduction of monoclonal antibodies, recombinant DNA, and protein engineering techniques has facilitated a rather rapid increase in the knowledge of pathogenetic mechanisms, as well as of protective antigens at the molecular level. This knowledge provides the basis for development of a new generation of vaccines. As a rule, these vaccines contain purified immunogens, or even isolated epitopes, identified and prepared by molecular biological techniques. The efforts to find better delivery systems and better adjuvants accompany the research on vaccines. 相似文献
6.
DNA vaccination represents one of the most recent novel approaches to vaccine development. Experimentally, DNA vaccines induce a broad range of long lasting immune responses including humoral and cell-mediated immunity against infectious diseases in humans and animals. Furthermore, DNA vaccines are potentially useful for the treatment of autoimmune diseases or cancer. However, most information on the efficacy of DNA vaccines has been generated in mice and studies in larger animals are limited. In this review, the potential application of DNA vaccines in livestock and pet animals are discussed. The principle of this new technology, its potency and future perspectives for use in veterinary medicine will be outlined. 相似文献
7.
Bazin H 《Comparative immunology, microbiology and infectious diseases》2003,26(5-6):293-308
Infectious diseases have always been a terrible scourge for humans. The appearance of these plagues, as they were called without distinction, was generally connected to various conditions: asters, climatic changes or religious reasons. The concept of contagious, and then infectious, diseases came slowly. Variolation, i.e. transmission of ‘virulent’ matter to induce a natural disease and the immunity against it, was brought from Constantinople to England by Lady Montague, in 1721. This ‘variolation’ technique was also often performed in veterinary medicine against diseases like sheep-pox or pleuropneumonia. As ‘vaccination’ is the term generally accepted for ‘immunisation’, variolation can be the word designating such a technique. The second period of the history of immunisation began, in 1880, with the studies of Pasteur and his collaborators. A great number of bacterial vaccines were developed: dead, live but attenuated or only parts of pathogens. The viruses were produced in animals, then in eggs and at last, in tissue cultures. Second generation vaccines appeared with genetic engineering: recombinant vaccines, vector vaccines, nucleic acids vaccines, and markers vaccines, among others. These novel technologies can permit the development of new ones and improve the quality of the vaccines already existing. 相似文献
8.
猪流行性腹泻(porcine epidemic diarrhea,PED)是危害养猪业健康发展的重要疾病之一,具有急性、高度传染性的特征,给养猪业造成了严重的经济损失。猪流行性腹泻病毒(porcine epidemic diarrhea virus,PEDV)感染会破坏动物机体的消化系统,造成患病猪食欲下降、呕吐以及严重腹泻等,且药物治愈后的仔猪也会因为生长发育不良等因素严重影响生产,给养殖户带来巨大的困扰。2010年PEDV高致病变异毒株在中国暴发流行,导致PED的发病率和死亡率大幅升高,严重影响中国养猪生产。此次PED的暴发流行引起了养猪行业的密切关注,相关研究领域的学者对PEDV致病机制和PED新型疫苗进行了更加深入的研究,亚单位疫苗、病毒活载体疫苗、细菌活载体疫苗、转基因植物疫苗和核酸疫苗5种PED新型疫苗相继被开发,并取得全新的突破和进展。与传统的PED灭活苗和PED弱毒疫苗相比,PED新型基因工程疫苗具有安全性好、制备简单、免疫效果好等优点。文章着重对PEDV发病机理和5种PED新型疫苗的研究进展展开综述,从而加深对PEDV和PED新型疫苗的了解,以期为PEDV感染的预防和控制措施提供参考。 相似文献
9.
Porcine epidemic diarrhea (PED) is one of the important diseases that endanger the healthy development of the pig industry.It has acute and highly infectious characteristics,causing severe economic losses to the pig industry.Porcine epidemic diarrhea virus (PEDV) infection could destroy the animal's digestive system,cause the appetite of sick pigs to decline,vomit,and severe diarrhea.And the piglets cured by drugs will also have a serious impact on production due to factors such as poor growth and development,which will bring huge problems to the farmers.The outbreak of PEDV highly pathogenic mutant strains in China in 2010 led to a significant increase in the incidence and mortality of PED,which severely affected pig production in China.The outbreak of PED has drawn close attention from the pig industry.Scholars in related research fields have conducted more in-depth research on the pathogenic mechanism of PEDV and the new PED vaccine.Five new types of PED vaccines,including subunit vaccine,virus live vector vaccine,bacterial live vector vaccine,transgenic plant vaccine and nucleic acid vaccine,have been developed successively,and new breakthroughs and progress have been made.Compared with the traditional PED inactivated vaccine and PED attenuated vaccine,the new PED genetically engineered vaccine has the advantages of good safety,simple preparation,and good immune effect.This article focuses on the pathogenesis of PEDV and the research progress of five new PED vaccines,so as to deepen our understanding of new PEDV and PED vaccines,in order to provide references for prevention and control measures of PEDV infection. 相似文献
10.
口蹄疫是一种感染牛、羊和猪等偶蹄动物、具有高度传染性的动物疫病。疫苗免疫是控制该病的关键措施之一,口蹄疫灭活疫苗在口蹄疫流行地区广泛使用。灭活疫苗中,完整口蹄疫病毒粒子(146S粒子)是至关重要的免疫抗原,它的数量和稳定性决定了疫苗的免疫效果。不同血清型,甚至同型不同毒株的口蹄疫病毒粒子稳定性不同,146S粒子在一定温度、酸、碱条件下容易分解为五聚体(12S粒子),导致疫苗免疫效力大幅下降。近年来口蹄疫病毒结构及其稳定性的分子基础研究取得了一定进展,为研究口蹄疫病毒稳定性提高疫苗质量,开发新型口蹄疫空衣壳疫苗提供了重要的理论基础。本文简要介绍了口蹄疫病毒结构基础、稳定性研究方法和研究进展。为同行了解口蹄疫病毒结构与免疫的关系,评价新型疫苗提供一些参考信息。 相似文献
11.
鸭疫里默氏菌病是严重危害鸭健康的细菌传染病之一,该病具有四季多发、传播途径广泛、其致病菌可在养殖场长期存在、经常继发或并发于其他疾病等特征。临床上,疫苗免疫是防控鸭疫里默氏菌病的重要方法。目前鸭疫里默氏菌疫苗主要有活疫苗、灭活疫苗、多价苗、联苗、菌体成分疫苗等,但都存在一定的缺陷和不足,因此研究更理想的疫苗是控制鸭疫里默氏菌病的重点。近年来,根据当地鸭疫里默氏菌血清型流行情况筛选当前流行血清型毒力较强的菌株研制灭活疫苗之外,还有通过基因工程技术构建原生质体结合的联苗和菌体成分疫苗。本文综述了鸭疫里默氏菌疫苗的研究、应用及应用效果和前景,同时讨论了各类型疫苗的优缺点,以期为以后鸭疫里默氏菌病疫苗的研究提供参考。 相似文献
12.
鸡传染性法氏囊病(IBD)是由鸡传染性法氏囊病病毒(IBDV)引起的雏鸡的一种高度接触性传染病,自1962年报道以来,世界上主要养禽国家和地区均有流行,给养禽业带来严重经济损失。目前,IBD防控的主要方法是采用疫苗接种,使易感雏鸡获得主动或被动免疫保护,因此疫苗的质量对临床上IBD的防控起着至关重要的作用。虽然各国均有较好的商品化疫苗,但随着IBDV毒株的不断变异,商品化疫苗的抗原性与流行毒株不能完全匹配,临床上免疫失败时有发生,因此迫切需要研发与临床流行毒株相匹配的新型疫苗用于IBD的防控。对近期IBD的基因缺失苗、亚单位疫苗、DNA疫苗以及活载体疫苗等新型疫苗的研究进展进行概述,以此为IBD新型疫苗的研究提供参考。 相似文献
13.
Present and future of veterinary viral vaccinology: a review 总被引:7,自引:0,他引:7
van Oirschot JT 《The Veterinary quarterly》2001,23(3):100-108
This review deals briefly with some key developments in veterinary vaccinology, lists the types of vaccines that are used for vaccinations commonly performed in food animals as well as in companion animals, and indicates that the practising veterinarian can select the best vaccine by comparing the results of efficacy studies. Diva (Differentiating Infected from Vaccinated Animals; also termed marker) vaccines and companion diagnostic tests have been developed that can be used for progammes aimed to control or eradicate virus infections. Vaccine-induced herd immunity, which can be measured relatively easily when diva vaccines are used, is a crucial issue in such programmes. Current vaccine research follows many routes towards novel vaccines, which can be divided into non-replicating ('killed') and replicating ('live') vaccines. Promising trends are the development of DNA vaccination, vector vaccines, and attenuation of DNA and RNA viruses by DNA technology. The lack of (in vitro) correlates of vaccine protection markedly hampers progress in vaccine research. Various characteristics of an 'ideal' vaccine are listed, such as multivalency and the induction of lifelong immunity after one non-invasive administration in animals with maternal immunity. Future research should be aimed at developing vaccines that approach the ideal as closely as possible and which are directed against diseases not yet controlled by vaccination and against newly emerging diseases. 相似文献
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Meyer G Deplanche M Schelcher F 《Comparative immunology, microbiology and infectious diseases》2008,31(2-3):191-225
Human (HRSV) and bovine (BRSV) respiratory syncytial viruses (RSV) are two closely related viruses, which are the most important causative agents of respiratory tract infections of young children and calves, respectively. BRSV vaccines have been available for nearly 2 decades. They probably have reduced the prevalence of RSV infection but their efficacy needs improvement. In contrast, despite decades of research, there is no currently licensed vaccine for the prevention of HRSV disease. Development of a HRSV vaccine for infants has been hindered by the lack of a relevant animal model that develops disease, the need to immunize immunologically immature young infants, the difficulty for live vaccines to find the right balance between attenuation and immunogenicity, and the risk of vaccine-associated disease. During the past 15 years, intensive research into a HRSV vaccine has yielded vaccine candidates, which have been evaluated in animal models and, for some of them, in clinical trials in humans. Recent formulations have focused on subunit vaccines with specific CD4+ Th-1 immune response-activating adjuvants and on genetically engineered live attenuated vaccines. It is likely that different HRSV vaccines and/or combinations of vaccines used sequentially will be needed for the various populations at risk. This review discusses the recent advances in RSV vaccine development. 相似文献
17.
Parasite vaccines--a reality? 总被引:40,自引:0,他引:40
Over the last decade, the anti-parasitics market has been the fastest growing sector of the overall $18 billion animal health market. While drugs for the treatment of parasites of livestock still dominate this sector and will continue to be developed or re-formulated, because of consumer demands for chemical-free food and of concerns regarding the environment and animal welfare there is a growing interest in the development of safe and effective vaccines. There is also a call for vaccines in the lucrative $3 billion-plus companion animal market. These demands for vaccines will add a greater impetus to an area that has seen tremendous success in the last 15 years. A number of anti-parasite vaccines have been developed, e.g. the recombinant 45w and EG95 oncosphere proteins against Taenia ovis and Echinococcus granulosis, respectively, and the Bm86 vaccine against Boophilus microplus. In addition, the cathepsin L vaccines against the liver fluke, Fasciola hepatica, and the H11 vaccine against Haemonchus contortus are progressing well. There are also many additional vaccine candidates for H. contortus and for other nematodes such as Ostertagia and Trichostrongylus spp. that may ultimately lead to broad-spectrum gastrointestinal worm vaccines. Live or attenuated-live vaccines are available for the control of avian coccidiosis, toxplasmosis in sheep and anaplasmosis in cattle, although molecular vaccines against protozoans are still proving elusive. The wealth of information in genomics, proteomics and immunology that has been forthcoming together will new methods of vaccine production and delivery should see many new vaccines reach the marketplace in the near future. 相似文献
18.
Bovine schistosomosis, caused by Schistosoma bovis, constitutes a serious veterinary problem in many parts of the world. The vaccination approaches for the control of bovine schistosomosis include the use of irradiation-attenuated S. bovis cercarial or schistosomular vaccines, S. bovis adult worms or whole-egg antigens and defined antigen vaccine. Irradiated S. bovis cercarial or schistosomular vaccines provide partial protection against S. bovis infection. However, this type of vaccine requires live infectious cercariae or viable schistosomula for induction of protection. Unfortunately, experimental immunizations with dead schistosome antigens have been largely unsuccessful. The surge of new techniques in cellular immunology and molecular biology has made possible the development of potential candidate vaccine antigens from various species of schistosomes including S. bovis. The efficiency of these vaccines has been evaluated in experimentally infected calves. These vaccines will probably replace the irradiated S. bovis vaccines. A broad-spectrum antischistosome vaccine which can kill a variety of human and animal schistosome species is yet to be produced. 相似文献
19.
Numerous infectious diseases caused by bacteria or viruses persist in developed and developing countries due to ongoing transmission among wildlife reservoir species. Such diseases become the target of control and management programmes in cases where they represent a threat to public health (for example rabies, sylvatic plague, Lyme disease), or livestock production (for example bovine tuberculosis, brucellosis, pseudorabies), or where they threaten the survival of endangered animal populations. In the majority of cases, lethal control operations are neither economically feasible nor publicly supported as a practical means for disease management. Prophylactic vaccination has emerged over the last 15 years as an alternative control strategy for wildlife diseases, mainly driven by the success of widescale oral rabies vaccination programmes for meso-carnivores in North America and Northern Europe. Different methods have been trialled for the effective delivery of wildlife vaccines in the field, however oral vaccination remains the most widely used approach. Successful implementation of an oral wildlife vaccine is dependent on a combination of three components: an efficacious immunogen, a suitable delivery vehicle, and a species-specific bait. This review outlines the major wildlife disease problems for which oral vaccination is currently under consideration as a disease management tool, and also focuses on the technological challenges that face wildlife vaccine development. The major conclusion is that attenuated or recombinant live microbes represent the most widely-used vaccines that can be delivered by the oral route; this in turn places major emphasis on effective delivery systems (to maintain vaccine viability), and on selective baiting systems, as the keys to wildlife vaccine success. Oral vaccination is a valuable adjunct or alternative strategy to culling for the control of diseases which persist in wildlife reservoirs. 相似文献
20.
H J Selbitz 《Berliner und Münchener tier?rztliche Wochenschrift》2001,114(11-12):428-432
Live vaccines have a number of advantages over inactivated ones--above all in respect of the stimulation of cell-mediated immune reactions. Various live vaccines, based on viruses, bacteria, fungi or parasites, have been approved for use in Germany in animals used as a source of food. Safety requirements obviously play a more important role for live vaccines, both in vaccine development and in batch testing, than with inactivated vaccines. Vaccine strains isolated from tissue samples must be clearly distinguishable from field strains. The safety of overdoses and the spread of the vaccine strain in the immunized animals have to be investigated, as well as shedding of the vaccine strain and its safety in non-target species. Any impact of a live vaccine strain on humans and the environment must be assessed. Live vaccines will remain an important research field in the long term, with efforts focused on developing deletion mutants and vector vaccines. 相似文献