Quality of horse F(ab')2 antitoxins and antirabies immunoglobulins: protein content and anticomplementary activity

Among other applications, immunotherapy is used for the post-exposure treatment and/or prophylaxis of important infectious diseases, such as botulism, diphtheria, tetanus and rabies. The effectiveness of serum therapy is widely proven, but improvements on the immunoglobulin purification process and on the quality control are necessary to reduce the amount of protein aggregates. These may trigger adverse reactions in patients by activating the complement system and inducing the generation of anaphylatoxins. Herein, we used immunochemical methods to predict the quality of horse F(ab′)2 anti-botulinum AB, anti-diphtheric, antitetanic and anti-rabies immunoglobulins, in terms of amount of proteins and protein aggregates. Methods Samples were submitted to protein quantification, SDS-PAGE, Western blot analysis and molecular exclusion chromatography. The anticomplementary activity was determined in vitro by detecting the production of C5a/C5a desArg, the most potent anaphylatoxin. Data were analyzed by one-way ANOVA followed by Tukey's post-test, and differences were considered statistically significant when p < 0.05. Results Horse F(ab′)2 antitoxins and anti-rabies immunoglobulin preparations presented different amounts of protein. SDS-PAGE and Western blot analyses revealed the presence of protein aggregates, non-immunoglobulin contaminants and, unexpectedly, IgG whole molecules in the samples, indicating the non-complete digestion of immunoglobulins. The chromatographic profiles of antitoxins and anti-rabies immunoglobulins allowed to estimate the percentage of contaminants and aggregates in the samples. Although protein aggregates were present, the samples were not able to induce the generation of C5a/C5a desArg in vitro, indicating that they probably contain acceptable levels of aggregates. Conclusions Anti-botulinum AB (bivalent), anti-diphtheric, antitetanic and anti-rabies horse F(ab′)2 immunoglobulins probably contain acceptable levels of aggregates, although other improvements on the preparations must be carried out. Protein profile analysis and in vitro anticomplementary activity of F(ab′)2 immunoglobulin preparations should be included as quality control steps, to ensure acceptable levels of aggregates, contaminants and whole IgG molecules on final products, reducing the chances of adverse reactions in patients.(AU)

Utilização da sílica nanoestruturada SBA-15 como adjuvante em imunizações com a vacina para hepatite B / Nanostructured SBA-15 silica as an adjuvant in immunizations with hepatitis B vaccine

Objective: To evaluate the applicability of SBA-15 silica as an adjuvant in immunizations with purified particles of the viral protein HBsAg, the main component of hepatitis B vaccine, Butang®, produced by Instituto Butantan. Methods: BALB/c mice orally or subcutaneously received 0.5 mug of HBsAg adsorbed/encapsulated to SBA-15 or adsorbed to Al(OH)3. To assess the secondary immune response, a subcutaneous booster was administered 30 days after the first immunization. Individual serum and fecal samples of each group were periodically collected for specific antibody titration by ELISA. Results: Analysis of secretory IgA showed that mice orally primed with HBsAg on SBA-15 had increased levels of specific antibodies in primary and secondary immune responses. Specific serum IgA and IgG titers in HBsAg:SBA-15-orally immunized mice reached higher levels after the booster, demonstrating the effectiveness of oral vaccination with the use of silica. All immunized groups showed higher IgG1 levels. Conclusion: Our results clearly indicate the promising use of SBA-15 as an adjuvant, especially in oral immunizations.

Objetivo: Demonstrar a aplicabilidade da sílica do tipo SBA-15 como adjuvante nas imunizações com a proteína recombinante HBsAg do vírus da hepatite B, principal componente da vacina Butang® produzida pelo Instituto Butantan. Métodos: Camundongos BALB/c receberam, pela via oral ou subcutânea, 0,5 mig do HbsAg adsorvido/encapsulado à SBA-15 ou adsorvido ao Al(OH)3. Para avaliar a resposta imune secundária, uma dose de reforço foi administrada subcutaneamente 30 dias após a primeira imunização. Amostras individuais de soro e fezes foram coletadas periodicamente para titulação de anticorpos específicos por ELISA. Resultados: A análise de IgA secretada mostrou que camundongos imunizados pela via oral com HbsAg em SBA-15 apresentaram aumento nos níveis de anticorpos específicos nas respostas primária e secundária. Ainda, após o reforço, observaram-se maiores níveis de IgA e IgG séricas anti-HBsAg no grupo preparado com HBsAg:SBA-15 pela via oral. Todos os grupos imunizados apresentaram maior produção de IgG1. Conclusão: Os resultados indicam o uso promissor da sílica SBA-15 como adjuvante, especialmente nas imunizações pela via oral.

VaxcineTM: an oil-based adjuvant for influenza vaccines

Vaccination is the method of choice for the prevention of influenza infection. However, the quantity of the antigen available, especially in the case of pandemics, often fails to meet the global demand. However, improved adjuvants can overcome this problem. Preliminary results obtained in this study revealed that one year after a single subcutaneous immunisation with influenza A H3N2 virus in an oil-based carrier, VaxcineTM, outbreed mice produced a high immunoglobulin G response that lasted for up to one year and exhibited less variation in titre compared with the response of the control group treated with alum. The haemagglutination-inhibition titres induced by VaxcineTM were also higher than those generated by alum. These data indicate that VaxcineTM is a good adjuvant candidate for seasonal influenza vaccines.