Abstract
Influenza virus is a leading cause of global morbidity and mortality due to acute lower respiratory infection, even with the widespread use of multiple licensed influenza vaccines. However, antigenic drift during influenza replication can cause vaccine-induced antibodies to poorly neutralize influenza virus, thereby reducing vaccine effectiveness. To help overcome this problem, we leveraged a hydrogel platform with influenza hemagglutinin (HA) protein to induce prolonged antigen exposure. The hydrogel platform, Vaccine Self-Assembling Immune Matrix (VacSIM(®)), in combination with recombinant influenza H1 or H3 HA protein antigens, increased antigen-specific antibody titers in vaccinated mice, which led to decreased disease severity after H1N1 infection for H1 HA-vaccinated mice and decreased lung viral titers after H3N2 challenge for H3 HA-vaccinated mice. Sera collected from mice immunized with VacSIM and HA also showed broader HAI activity, increasing by 1-3 log against a panel of influenza viruses. These results were consistent with the use of cocktail immunization, containing both an H1 and H3 HA, where mice immunized with VacSIM had an increase in antigen-specific antibody titers and decreased disease severity and lung viral titers against H1N1 and H3N2 influenza challenges, respectively. Finally, it was determined that a single immunization with VacSIM and H1 HA could provide protection against lethal H1N1 challenge compared to a group without VacSIM. In summary, we demonstrate that use of the slow-release platform VacSIM can improve the host immune response to vaccination and increase protection against influenza infection.