新城疫壳聚糖微球疫苗免疫效果的研究

鸡新城疫是由新城疫病毒引起的鸡的一种急性、烈性、高度接触性传染病,是危害养禽业的最严重疫病之一。控制新城疫最根本的措施是进行有效的疫苗接种,目前常用的疫苗是弱毒活疫苗和灭活疫苗,但二者在实际应用中均存在一定的局限性。口服微球疫苗可以诱导较强的粘膜免疫;同时还能够诱导产生系统的体液免疫和细胞免疫,已成为ND疫苗研究的热点。以壳聚糖为囊材,新城疫La Sota抗原液为芯材,戊二醛为交联剂,制备出新城疫壳聚糖微球疫苗,通过了实验室安全检验和效力检验。将新城疫壳聚糖微球疫苗与LaSota活疫苗和新城疫油乳剂灭活苗分别免疫SPF鸡,利用MTT、血凝抑制法(HI)和ELISA等分别检测不同疫苗免疫后的细胞免疫、体液免疫和粘膜免疫抗体IgA,并在当免疫鸡HI抗体降到23的情况下进行了攻毒试验。结果表明,新城疫壳聚糖微球疫苗安全性好,免疫后可刺激机体产生较强的细胞免疫、体液免疫和局粘膜免疫,具有较好的保护作用。     

mRNA疫苗非病毒载体递送系统研究进展*

新型冠状病毒肺炎(Corona Virus Disease 2019,COVID-19)疫情的暴发导致全球迫切需要大量有效的疫苗来应对。mRNA疫苗具有良好的安全性,且研发周期短,成为目前最有潜力的疫苗之一,在传染病和肿瘤研究领域也引发了更多关注。随着技术创新,mRNA不稳定性、翻译效率低等缺点得到较大改善。如何安全高效地将mRNA递送至靶细胞仍是阻碍mRNA研究的一大挑战。综述目前应用于mRNA疫苗体内递送的非病毒载体递送系统,以及mRNA在传染病疫苗和肿瘤疫苗中的应用现状,旨在为mRNA疫苗研发提供参考。     

腺病毒载体疫苗的临床研究进展

腺病毒载体是目前最有应用前景的疫苗载体之一,具有高表达、可同时诱导特异性体液免疫和细胞免疫反应、安全性好、易于制备、无需添加佐剂等优点,被广泛应用于各种预防性或治疗性疫苗的研发。本文就进入临床试验的重要腺病毒载体疫苗作一综述。     

对研发新型结核病疫苗的分析和展望

结核病是公共卫生当前面临的重要问题。由于BCG预防效果不佳,研究和开发新型结核病疫苗显得必须且急迫。新型结核病疫苗的研究开发路径和观念也经历了变迁,当前主流的研发路径有重组BCG或重组结核菌、重组痘病毒或重组腺病毒载体疫苗、蛋白质亚单位或重组融合蛋白质亚单位疫苗三类,它们在疫苗效力前景,抗原选型、配方、剂型,免疫应答,疫苗生产,疫苗质量控制,临床前研究动物试验,临床试验和使用,对结核病公共卫生政策的影响等方面各有优劣。新型结核病疫苗的成功研发,还需要病原学、发病机制、免疫学和疫苗研发科学的进一步努力。     

美国微生物学会杂志摘要（2005．12 ASM News，2006．1 Microbes）

1．目前,禽流感仍是全球微生物学界普遍关心的问题。Webster认为单纯扑杀感染的禽不是一项有效措施。泰国曾以扑杀感染禽的方法控制了疫情近1年,但HSN1病毒已重返。因HSNl病毒在亚洲野鸟中存在,故控制禽流感不能仅靠扑杀。由于在亚洲的小养殖场是散养,没有将家禽与野鸟隔离的网等设施,疫苗免疫成为很重要的措施。印度尼西亚科技部的Amin Soebandrio认为有些疫苗质量有问题,禽类免疫后禽类感染H5N1病毒后不死,反而继续排毒。据认为,好的疫苗注射1次即可产生有效保护,因此应不断研发质量高的用于禽类的疫苗。     

新城疫基因工程疫苗研究进展

新城疫基因工程疫苗研究进展霍龙飞,王莉林,卢景良（哈尔滨兽医研究所备医生物技术国家重点实验室,哈尔滨）鸡新城疫（ＮＤ）是由新城疫病毒（Ｎｅｗ－ｃａｓｔｌｅＤｉｓｅａｓｅＶｉｒｕｓ,ＮＤＶ）所致的一种死亡率很高急性败血性高度接触性禽类传染病,也是养禽业...     

COVID-19疫苗研究现状*

2019年底于中国武汉暴发的新型冠状病毒肺炎疫情来势凶猛,迅速蔓延全球,并被世界卫生组织列为“国际关注的突发公共卫生事件”,给全人类的健康及经济发展造成难以估量的损害。新型冠状病毒对人群普遍易感且传染性强,在无特效药物及治疗手段的情况下,疫苗接种是防控COVID-19疫情最有效且最经济的途径。目前全球疫苗研发正在加速进行,各国之间通力合作,共同应对此次疫情。主要对目前正在研发的针对SARS-CoV-2的灭活疫苗、病毒载体疫苗、基因工程重组亚单位疫苗、核酸疫苗的研究进展进行综述。     

COVID-19疫苗研究现状*

2019年底于中国武汉暴发的新型冠状病毒肺炎疫情来势凶猛,迅速蔓延全球,并被世界卫生组织列为“国际关注的突发公共卫生事件”,给全人类的健康及经济发展造成难以估量的损害。新型冠状病毒对人群普遍易感且传染性强,在无特效药物及治疗手段的情况下,疫苗接种是防控COVID-19疫情最有效且最经济的途径。目前全球疫苗研发正在加速进行,各国之间通力合作,共同应对此次疫情。主要对目前正在研发的针对SARS-CoV-2的灭活疫苗、病毒载体疫苗、基因工程重组亚单位疫苗、核酸疫苗的研究进展进行综述。     

微生物介导的新城疫病毒疫苗的研制现状

新城疫病毒引起的新城疫是一种禽类急性接触性传染病,采用疫苗防治该病是当前研究的热点领域之一。HN/F蛋白是2种有效的疫苗候选分子,乳酸乳球菌、鼠伤寒沙门菌、单增李斯特菌、根癌农杆菌、鸡痘病毒、牛痘病毒、鸽痘病毒、禽红白血病病毒、禽副粘病毒3型、传染性法氏囊病病毒和传染性气管炎病毒等微生物经过改造后可成为理想的疫苗载体。本文综述了重组乳酸乳球菌(rLL-HN)、重组鼠伤寒沙门菌(rSt-F和rSt-HN)、重组单增李斯特菌(rLm-F)、重组根癌农杆菌(rAt-F)、重组鸡痘病毒(rFPV-HN、rFPV-F-gB和rFPV-F-HN-gB)、重组牛痘病毒(rVV-F)、重组鸽痘病毒(rPPV-F)、重组禽红白血病病毒(rAEV-HN)、重组禽副粘病毒3型(rAPMV-F)、重组传染性法氏囊病病毒(rIBDV-HN)和重组传染性气管炎病毒(rIBV-HN)等疫苗的构建及其免疫机制的研制现状。     

人用H7N9疫苗的研究进展

2013年3月,在中国首次出现低致病性H7N9病毒感染者并致死的病例。迄今为止,中国共出现5次H7N9病毒流行的疫情。其间,H7N9病毒不断发生变异,新的基因型以及高致病性H7N9病毒相继出现。变异的H7N9病毒对禽类养殖业和人类的公共卫生造成了严重的威胁,疫苗是预防H7N9病毒流行的有效措施。目前,全世界尚无临床可用的人用H7N9疫苗,但各类备选H7N9疫苗都在研究中,如灭活疫苗、减毒疫苗、亚单位疫苗、病毒样颗粒疫苗、核酸疫苗和病毒载体疫苗等。其中,一些H7N9疫苗已进入临床研究阶段。现对各类人用H7N9疫苗的研究进展作一概述。     

Newcastle disease virus-like particles as a platform for the development of vaccines for human and agricultural pathogens

Vaccination is the single most effective way to control viral diseases. However, many currently used vaccines have safety concerns, efficacy issues or production problems. For other viral pathogens, classic approaches to vaccine development have, thus far, been unsuccessful. Virus-like particles (VLPs) are increasingly being considered as vaccine candidates because they offer significant advantages over many currently used vaccines or developing vaccine technologies. VLPs formed with structural proteins of Newcastle disease virus, an avian paramyxovirus, are a potential vaccine candidate for Newcastle disease in poultry. More importantly, these VLPs are a novel, uniquely versatile VLP platform for the rapid construction of effective vaccine candidates for many human pathogens, including genetically complex viruses and viruses for which no vaccines currently exist.     

植物口服疫苗的研究进展

植物口服疫苗是通过转基因植物生产,通过口服的方式预防疾病的生物制品.作为一种新型疫苗,其研究开始于三十几年前.由于植物口服疫苗可以最大程度地降低传统疫苗的潜在风险,在疫苗生产中具有优势,因此拥有良好的商业生产前景.植物疫苗价格低廉,生产过程安全,可产生与注射疫苗相似效价效果,无论是在控制养殖业抗生素滥用的情况下作为替代...     

Efficacy of Single Dose of a Bivalent Vaccine Containing Inactivated Newcastle Disease Virus and Reassortant Highly Pathogenic Avian Influenza H5N1 Virus against Lethal HPAI and NDV Infection in Chickens

Highly pathogenic avian influenza (HPAI) and Newcastle disease (ND) are 2 devastating diseases of poultry, which cause great economic losses to the poultry industry. In the present study, we developed a bivalent vaccine containing antigens of inactivated ND and reassortant HPAI H5N1 viruses as a candidate poultry vaccine, and we evaluated its immunogenicity and protective efficacy in specific pathogen-free chickens. The 6∶2 reassortant H5N1 vaccine strain containing the surface genes of the A/Chicken/Korea/ES/2003(H5N1) virus was successfully generated by reverse genetics. A polybasic cleavage site of the hemagglutinin segment was replaced by a monobasic cleavage site. We characterized the reverse genetics-derived reassortant HPAI H5N1 clade 2.5 vaccine strain by evaluating its growth kinetics in eggs, minimum effective dose in chickens, and cross-clade immunogenicity against HPAI clade 1 and 2. The bivalent vaccine was prepared by emulsifying inactivated ND (La Sota strain) and reassortant HPAI viruses with Montanide ISA 70 adjuvant. A single immunization with this vaccine induced high levels of hemagglutination-inhibiting antibody titers and protected chickens against a lethal challenge with the wild-type HPAI and ND viruses. Our results demonstrate that the bivalent, inactivated vaccine developed in this study is a promising approach for the control of both HPAI H5N1 and ND viral infections.     

Newcastle disease vaccines

Newcastle disease (ND) is a worldwide problem with severe economic implications, affecting chickens, turkeys and other birds. Newcastle disease virus (NDV), a member of the Paramyxoviridae group can cause disease of diverse severity in accordance with environmental factors. NDV strains are classified according to their virulence into three categories. The lentogenic strains are very mild and naturally inhabit healthy flocks. They can be used as live vaccines even for young chicks. Killed vaccines can be produced from the same viruses following inactivation. Mesogenic ND viruses, which cause mild or inapparent respiratory infections, have recently been banned in many countries even for killed vaccine production due to fears of disease emergence. Velogenic strains are the causative agents of the disease and can be used for the purpose of vaccine challenge test. Production and use of Newcastle disease vaccines are discussed in this review.     

腺病毒载体在疫苗研究中的应用

以病毒为载体的活疫苗为疾病预防和治疗研究提供了新手段。目前用于疫苗研究的病毒载体主要包括痘苗病毒载体、腺病毒载体、腺相关病毒载体、单纯疱疹病毒载体及逆转录病毒载体等。其中,重组腺病毒载体因其基因组大小适中,易于基因重组操作,繁殖滴度高,易于大量制备和保存,宿主范围广,转导效率高,安全性好,能刺激机体产生强烈的体液和细胞免疫反应等特点,而被广泛应用于重要感染性疾病及恶性肿瘤的疫苗研究。腺病毒载体在人免疫缺陷病毒(HIV)疫苗研究和临床试验中的成败更是备受关注。然而,与其他载体疫苗一样,机体对载体的免疫反应仍是阻碍腺病毒载体疫苗在临床中广泛应用的主要问题。那么,腺病毒载体解决这类问题的优势何在?我们简要综述腺病毒载体的特点及其在疫苗研究中的应用和存在的问题,为进一步优化和利用腺病毒载体在疫苗方面的研究提供参考。     

Adjuvanticity of compound polysaccharides on chickens against Newcastle disease and avian influenza vaccine

This study was conducted to evaluate the effects of compound polysaccharides (cPS) on the immune responses via chicken models. First, in screening experiment, a comprehensive analysis for immunomodulatory activity of four cPSs, including Astragalus polysaccharides (APS), Epimedium polysaccharides (EPS), sulfated APS (sAPS) and sulfated EPS (sEPS), was performed in vitro and in vivo. APS-sEPS was picked out having the best effect on lymphocyte proliferation and raising the antibody titers. Therefore, the adjuvanticities of APS-sEPS on Newcastle disease (ND) and avian influenza (AI) vaccine were further validated. Chickens were administrated with ND or AI vaccines containing APS-sEPS of 150, 100 and 50 mg/kg, respectively, taking oil adjuvant vaccine as control. It was observed ND or AI antibody titers and lymphocyte proliferation were enhanced at 100 mg/kg of APS-sEPS. In conclusion, appropriate dose of APS-sEPS may be a safe and efficacious immune stimulator candidate suitable for vaccines.     

Vaccines against malaria

There is no licenced vaccine against any human parasitic disease and Plasmodium falciparum malaria, a major cause of infectious mortality, presents a great challenge to vaccine developers. This has led to the assessment of a wide variety of approaches to malaria vaccine design and development, assisted by the availability of a safe challenge model for small-scale efficacy testing of vaccine candidates. Malaria vaccine development has been at the forefront of assessing many new vaccine technologies including novel adjuvants, vectored prime-boost regimes and the concept of community vaccination to block malaria transmission. Most current vaccine candidates target a single stage of the parasite's life cycle and vaccines against the early pre-erythrocytic stages have shown most success. A protein in adjuvant vaccine, working through antibodies against sporozoites, and viral vector vaccines targeting the intracellular liver-stage parasite with cellular immunity show partial efficacy in humans, and the anti-sporozoite vaccine is currently in phase III trials. However, a more effective malaria vaccine suitable for widespread cost-effective deployment is likely to require a multi-component vaccine targeting more than one life cycle stage. The most attractive near-term approach to develop such a product is to combine existing partially effective pre-erythrocytic vaccine candidates.     

Adjuvants in tuberculosis vaccine development

Tuberculosis remains a major public health problem around the world. Because the Mycobacterium bovis Bacilli–Calmette–Guerin (BCG) vaccine fails to protect adults from pulmonary tuberculosis, there is an urgent need for improved vaccine formulations. Unlike BCG, recombinant vaccines purified from bacterial expression vectors, as well as naked DNA, require an additional adjuvant. Recent improvements in our understanding of disease immunopathology, together with advances in biochemical and molecular techniques, have permitted the successful development of promising tuberculosis vaccine delivery and adjuvant combinations for human use. Here, we summarize the current state of adjuvant development and its impact on tuberculosis vaccine progress.     

Accelerating vaccine development and deployment: report of a Royal Society satellite meeting

The Royal Society convened a meeting on the 17th and 18th November 2010 to review the current ways in which vaccines are developed and deployed, and to make recommendations as to how each of these processes might be accelerated. The meeting brought together academics, industry representatives, research sponsors, regulators, government advisors and representatives of international public health agencies from a broad geographical background. Discussions were held under Chatham House rules. High-throughput screening of new vaccine antigens and candidates was seen as a driving force for vaccine discovery. Multi-stakeholder, small-scale manufacturing facilities capable of rapid production of clinical grade vaccines are currently too few and need to be expanded. In both the human and veterinary areas, there is a need for tiered regulatory standards, differentially tailored for experimental and commercial vaccines, to allow accelerated vaccine efficacy testing. Improved cross-fertilization of knowledge between industry and academia, and between human and veterinary vaccine developers, could lead to more rapid application of promising approaches and technologies to new product development. Identification of best-practices and development of checklists for product development plans and implementation programmes were seen as low-cost opportunities to shorten the timeline for vaccine progression from the laboratory bench to the people who need it.     

The influence of the inactivating agent on the antigen content of inactivated Newcastle disease vaccines assessed by the in vitro potency test

An in vitro potency test has recently been included in the European Pharmacopoeia (EP) monograph (01/2007:0870) to assess the potency of inactivated Newcastle disease (ND) vaccines. This enzyme linked immunosorbent assay (ELISA) is an attractive alternative for the existing in vivo potency tests especially with regard to the objective of the European Authorities to Replace, Reduce and Refine the use of laboratory animals for production and quality control of immunobiologicals.In the present study the influence of the inactivant on the antigen content established by ELISA was evaluated. Therefore, oil based vaccines containing similar concentrations of β-propiolactone (BPL) or formaldehyde inactivated Newcastle disease virus (NDV) were examined by ELISA and in the in vivo potency tests outlined in the EP.The results obtained demonstrate that the use of formaldehyde as inactivant lowered the in vitro potency compared to BPL as inactivant. In contrast, the in vivo potency was not affected. Therefore, the ELISA should not be used to compare the potency of commercial ND vaccines containing formaldehyde inactivated NDV with those containing BPL inactivated NDV. However, the ELISA is considered an attractive alternative for the existing in vivo potency tests since it can be used by vaccine manufacturers for the release of inactivated ND vaccines.