Cold adaptation improves the growth of seasonal influenza B vaccine viruses.

Gene reassortment has proved useful in improving yields of influenza A antigens of egg-based inactivated vaccines, but similar approaches have been difficult with influenza B antigens. Current regulations for influenza vaccine seed viruses limit the number of egg passages and as a result resultant yields from influenza B vaccine seed viruses are frequently inconsistent. Therefore, reliable approaches to enhance yields of influenza B vaccine seed viruses are required for efficient vaccine manufacture. In the present study three stable cold-adapted (ca) mutants, caF, caM and caB derived from seasonal epidemic strains, B/Florida/4/2006, B/Malaysia/2506/2004 and B/Brisbane/60/2008 were prepared, which produced high hemagglutinin antigen yields and also increased viral yields of reassortants possessing the desired 6:2 gene constellation. The results demonstrate that consistent improvements in yields of influenza B viruses can be obtained by cold adaptation following extended passage. Taken together, the three ca viruses were shown to have potential as donor viruses for the preparation of high-yielding influenza B vaccine viruses by reassortment.

Scientific investigations into febrile reactions observed in the paediatric population following vaccination with a 2010 Southern Hemisphere Trivalent Influenza Vaccine.

During the 2010 Southern Hemisphere (SH) influenza season, there was an unexpected increase in the number of febrile reactions reported in the paediatric population in Australia shortly after vaccination with the CSL 2010 trivalent influenza vaccine (TIV) compared to previous seasons. A series of scientific investigations were initiated to identify the root cause of these adverse events, including in vitro cytokine/chemokine assays following stimulation of adult and paediatric whole blood, as well as mammalian cell lines and primary cells, profiling of molecular signatures using microarrays, and in vivo studies in rabbits, ferrets, new born rats and rhesus non-human primates (NHPs). Various TIVs (approved commercial vaccines as well as re-engineered TIVs) and their individual monovalent pool harvest (MPH) components were examined in these assays and in animal models. Although the scientific investigations are ongoing, the current working hypothesis is that the increase in febrile adverse events reported in Australia after vaccination with the CSL 2010 SH TIV may be due to a combination of both the introduction of three entirely new strains in the CSL 2010 SH TIV, and differences in the manufacturing processes used to manufacture CSL TIVs compared to other licensed TIVs on the market. Identification of the causal component(s) may result in the identification of surrogate assays that can assist in the formulation of TIVs to minimise the future incidence of febrile reactions in the paediatric population.

The development of vaccine viruses against pandemic A(H1N1) influenza.

Wild type human influenza viruses do not usually grow well in embryonated hens' eggs, the substrate of choice for the production of inactivated influenza vaccine, and vaccine viruses need to be developed specifically for this purpose. In the event of a pandemic of influenza, vaccine viruses need to be created with utmost speed. At the onset of the current A(H1N1) pandemic in April 2009, a network of laboratories began a race against time to develop suitable candidate vaccine viruses. Two approaches were followed, the classical reassortment approach and the more recent reverse genetics approach. This report describes the development and the characteristics of current pandemic H1N1 candidate vaccine viruses.