The use of influenza vaccines and remantadine for protection against influenza in industrial enterprises

The effectiveness of inactivated and live influenza vaccines and remantidin was studied in persons with different annual morbidity rate in influenza and acute respiratory diseases (ARD). After three and more years of immunization with the inactivated vaccine the number of seroconversions to viruses A (H1N1) and A (H3N2) in vaccinees decreased, respectively, from 75.0 to 26.0% and from 79.3 to 38.8%, and after an interval of two years or the alternation of inactivated and live vaccines the number of seroconversions increased to 57.9-64.0%. The significant decrease of morbidity rate in influenza and ARD were observed only in persons, having had frequent ARD in their medical history and immunized with live and inactivated vaccines simultaneously or separately with the alternation of these vaccines every year (the effectiveness index being equal to 1.7-1.8). At the period of epidemic the controlled administration of remantadin to persons with contraindications to immunization ensured the decrease of morbidity rate in influenza 1.5-1.8 times; in vaccinees, highly susceptible to ARD, the administration of remantadin decreased morbidity rate 2.3 times.     

Analysis of genome integrity of influenza virus in formaldehyde-inactivated split vaccines

Although inactivated split-virus influenza vaccines are widely used to render protection against the viral infection, information regarding the effects of the vaccine preparation on the integrity of the viral genomes is currently very limited. In the present study, to gain insight into the physical and genetic alterations of RNA viral genomes in the course of the vaccine preparation, we analyzed the influenza virus A H1N1 hemagglutinin (HA) genome segment in a conventional split-virus influenza vaccine inactivated by formaldehyde, which encodes the major surface protein of the virus. The vaccine solutions were treated with proteinase K prior to RNA purification, and viral genomic RNA was successfully retrieved up to almost eightfold higher than samples without the treatment. Despite the high yield, no full-length bands of the influenza viral genomes were identifiable upon electrophoresis due to severe degradation. Interestingly, however, we were able to amplify a variety of genomic regions including a fragment covering the full-length HA gene using cDNA. Furthermore, sequencing of a series of the fragments for confirmation revealed that the rate of base alteration of the gene in the vaccine was approximately 0.1 %, which is comparable to the spontaneous error rate occurring during PCR. We next constructed a GST expression vector carrying the full-length HA fragment cloned from the vaccine and confirmed that the correct size of the expected GST-fused HA protein was expressed. Taken together, these results demonstrate that a full-length HA RNA genome fragment with comparatively intact sequence information may exist in the inactivated split-virus vaccine. Therefore, these experimental findings on the properties of the HA RNA in the influenza vaccine, may contribute to cautious use of the vaccine in a variety of research areas and protocols.     

The quantification of the haemagglutinin content of influenza whole virus and Tween-ether split vaccines

Monovalent whole virus and Tween-ether split vaccines prepared from influenza A/Bangkok, A/Brazil and B/Singapore were assayed for haemagglutinin content using single radial immunodiffusion (SRID), quantitative sodium dodecyl sulphate-polyacrylamide gel electrophoresis (SDS-PAGE) and immunization of guinea pigs. When SRID was performed with split vaccines, haemagglutinin values were consistently recorded which were in the range of 50 to 25% of the values obtained before disruption of virions. When, however, disruption was conducted in the presence of excess detergent, thus preventing aggregate formation of solubilized haemagglutinin, test values comparable with those of whole virus vaccines were obtained. In agreement with these results, immunization experiments revealed that whole virus and corresponding split vaccines exhibited comparable immunogenicity in guinea pigs. Additionally it could be calculated from SDS-PAGE and densitometer tracings, obtained by scanning the gels after staining with either Coomassie blue or FITC-Con A, that 90 to 95% of whole virus HA2 was recovered in Tween-ether split vaccines. On the basis of these findings we conclude that precise quantification of Tween-ether split vaccines is not possible by the SRID test alone. As aggregate formation of solubilized haemagglutinin occurs, we suggest that either a physico-chemical method including a disaggregation procedure, such as SDS treatment, or immunological evaluation of the original whole virus preparation before disruption of virions should be applied as an additional criterion for quantification of influenza Tween-ether split vaccines.     

The choice of adjuvants in Mycoplasma vaccines

The use of adjuvants in vaccine production is an important aspect of potent vaccines. This investigation was concerned with finding the most efficient adjuvants for use in Mycoplasma vaccines produced in Nigeria. Four different vaccines were produced from the Gladysdale strain of Mycoplasma mycoides subspecies mycoides. They differed depending on the type of adjuvants used. Each vaccine was used to vaccinate eight cattle using a dose of 1 ml. Two other groups of eight cattle were used as controls. One of the two groups received 1 ml dose of inactivated Gladysdale vaccine without adjuvant while the second group received 1 ml dose of saline. The number of cattle that had the peak complement fixing (CF) antibody titres of 1/80 in each group of cattle was four for vaccine containing aluminium hydroxide gel, eight for vaccine containing liquid paraffin, one for vaccine containing sodium alginate and one for vaccine without adjuvant. Seven cattle from the group vaccinated with vaccine containing Freund's incomplete adjuvant had peak CF antibody titres of 1/80 or higher. The two groups vaccinated with vaccine containing liquid paraffin and Freund's incomplete adjuvant survived challenge at 6 months post vaccination. Freund's incomplete adjuvant and liquid paraffin containing 10% Arlacel A are the most efficient adjuvants.     

Archaeosomes as adjuvants for combination vaccines

The present study evaluated the potential of archaesomes, prepared from the total polar lipids extracted from Methanobrevibacter smithii, as adjuvants for combination (multivalent) vaccines. Groups of Balb/c mice were immunized subcutaneously at day 0 and 21 with one of the following vaccines: trivalent vaccine formulated by the simultaneous co-encapsulation of bovine serum albumine (BSA), ovalbumin (OVA) and hen egg lysozyme (HEL) into archaeosomes (CEC vaccine); an univalent archaeosome vaccine (UVE vaccine) containing either BSA, OVA or HEL; or an admixture vaccine (AMC vaccine) consisting of the three UVE vaccines. Serum specific antibody (IgG + M) responses were determined at day 32, 112 and 203, and specific IgG1 and IgG2a responses were determined at day 112. Mice immunized with the CEC of AMC vaccine developed strong and sustained specific antibody responses to all three antigens at a magnitude similar to those seen in control mice immunized with UVE vaccines. Moreover, the serum BSA-, OVA-, and HEL-specific IgG1 and IgG2a levels in the CEC and AMC immunized mice were overall comparable to those of the UVE immunized control mice. Boosting CEC and AMC vaccinated mice with antigens alone at day 203 elicited strong antibody memory responses, comparable to those in the UVE vaccinated groups. These results show that archaeosomes could be used as adjuvants in developing combination vaccines.     

Cytokines as adjuvants for avian vaccines

The worldwide trend towards a reduced reliance on in-feed antibiotics has increased the pressure to develop alternative strategies to manage infectious diseases in poultry. With this in mind, there is a great emphasis on vaccine use and the enhancement of existing vaccines to provide long-term protection. Currently existing adjuvants for poultry can have deleterious side-effects, such as inflammation, resulting in the down-grading of meat quality and a subsequent reduction in profits. Therefore, to enhance the use of vaccination, alternative adjuvants must be developed. The use of recombinant cytokines as adjuvants in poultry is attracting considerable attention, and their potential role as such has been addressed by several studies. The recent identification of a number of chicken cytokine genes has provided the possibility to study their effectiveness in enhancing the immune response during infection and vaccination. This review focuses on the recent studies involving the assessment of cytokines as vaccine adjuvants.     

Soluble recombinant influenza vaccines.

Soluble, recombinant forms of influenza A virus haemagglutinin and neuraminidase have been produced in cells of lower eukaryotes, and shown in a mouse model to induce complete protective immunity against a lethal virus challenge. Soluble neuraminidase, produced in a baculovirus system, consisted of tetramers, dimers and monomers. Only the tetramers were enzymatically active. The immunogenicity decreased very considerably in the order tetra > di > mono. Therefore, we fused the head part of the neuraminidase gene to a tetramerizing leucine zipper sequence; the resulting product was enzymatically active, tetrameric neuraminidase. The protective immunity induced by this engineered neuraminidase, however, remained fairly strain-specific. A third influenza A virus protein, the M2 protein, has only 23 amino acids exposed on the outer membrane surface. This extracellular part, M2e, has been remarkably conserved in all human influenza A strains since 1933. By fusing the M2e sequence to hepatitis B virus core protein, we could obtain highly immunogenic particles that induced complete, strain-independent, long-lasting protection in mice against a lethal viral challenge. Native M2 is a tetrameric protein and this conformation of the M2e part can also be mimicked by fusing this sequence to a tetramerizing leucine zipper. The potential of the resulting protein as a vaccine candidate remains to be evaluated.     

Developing vaccines against pandemic influenza.

Pandemic influenza presents special problems for vaccine development. There must be a balance between rapid availability of vaccine and the safeguards to ensure safety, quality and efficacy of vaccine. Vaccine was developed for the pandemics of 1957, 1968, 1977 and for the pandemic alert of 1976. This experience is compared with that gained in developing vaccines for a possible H5N1 pandemic in 1997-1998. Our ability to mass produce influenza vaccines against a pandemic threat was well illustrated by the production of over 150 million doses of 'swine flu' vaccine in the USA within a 3 month period in 1976. However, there is cause for concern that the lead time to begin vaccine production is likely to be about 7-8 months. Attempts to reduce this time should receive urgent attention. Immunogenicity of vaccines in pandemic situations is compared over the period 1968-1998. A consistent feature of the vaccine trials is the demonstration that one conventional 15 microg haemagglutinin dose of vaccine is not sufficiently immunogenic in naive individuals. Much larger doses or two lower doses are needed to induce satisfactory immunity. There is some evidence that whole-virus vaccines are more immunogenic than split or subunit vaccines, but this needs substantiating by further studies. H5 vaccines appeared to be particularly poor immunogens and there is evidence that an adjuvant may be needed. Prospects for improving the development of pandemic vaccines are discussed.     

Recent developments in adjuvants for vaccines against infectious diseases

New generation vaccines, particularly those based on recombinant proteins and DNA, are likely to be less reactogenic than traditional vaccines, but are also less immunogenic. Therefore, there is an urgent need for the development of new and improved vaccine adjuvants. Adjuvants can be broadly separated into two classes, based on their principal mechanisms of action; vaccine delivery systems and 'immunostimulatory adjuvants'. Vaccine delivery systems are generally particulate e.g. emulsions, microparticles, iscoms and liposomes, and mainly function to target associated antigens into antigen presenting cells (APC). In contrast, immunostimulatory adjuvants are predominantly derived from pathogens and often represent pathogen associated molecular patterns (PAMP) e.g. LPS, MPL, CpG DNA, which activate cells of the innate immune system. Once activated, cells of innate immunity drive and focus the acquired immune response. In some studies, delivery systems and immunostimulatory agents have been combined to prepare adjuvant delivery systems, which are designed for more effective delivery of the immunostimulatory adjuvant into APC. Recent progress in innate immunity is beginning to yield insight into the initiation of immune responses and the ways in which immunostimulatory adjuvants may enhance this process. However, a rational approach to the development of new and more effective vaccine adjuvants will require much further work to better define the mechanisms of action of existing adjuvants. The discovery of more potent adjuvants may allow the development of vaccines against infectious agents such as HIV which do not naturally elicit protective immunity. New adjuvants may also allow vaccines to be delivered mucosally.     

四价流感病毒裂解疫苗的稳定性

目的评价四价流感病毒裂解疫苗的稳定性,为疫苗的有效期提供依据。方法分别将A1(H1N1)、A3(H3N2)、B/Victoria和B/Yamagata等4株毒株制备单价原液,生产6批疫苗(不含硫柳汞),评价疫苗分别在(37±2)℃、(25±2)℃和(6±2)℃条件下的稳定性。结果四价流感病毒裂解疫苗在(37±2)℃保存10 d、在(25±2)℃保存3个月、在(6±2)℃保存15个月,疫苗各项指标均符合企业注册标准和《中华人民共和国药典》2015版(三部)的要求。结论四价流感病毒裂解疫苗具有良好的稳定性,在(6±2)℃可稳定保存15个月。     

The development and use of vaccine adjuvants

Interest in vaccine adjuvants is intense and growing, because many of the new subunit vaccine candidates lack sufficient immunogenicity to be clinically useful. In this review, I have emphasized modern vaccine adjuvants injected parenterally, or administered orally, intranasally, or transcutaneously with licensed or experimental vaccines in humans. Every adjuvant has a complex and often multi-factorial immunological mechanism, usually poorly understood in vivo. Many determinants of adjuvanticity exist, and each adjuvanted vaccine is unique. Adjuvant safety is critical and can enhance, retard, or stop development of an adjuvanted vaccine. The choice of an adjuvant often depends upon expensive experimental trial and error, upon cost, and upon commercial availability. Extensive regulatory and administrative support is required to conduct clinical trials of adjuvanted vaccines. Finally, comparative adjuvant trials where one antigen is formulated with different adjuvants and administered by a common protocol to animals and humans can accelerate vaccine development.     

流感病毒样颗粒疫苗研究进展

流行性感冒(流感)是由正粘病毒科的负链RNA流感病毒引起的一种上呼吸道急性传染病,它传染性强、传播快、潜伏期短、发病率高,严重影响着人类的健康和全球经济的发展,对老年人和婴幼儿危害尤其大。在人类历史上曾经历过多次流感大流