Thus, 800 μg of sHZ showed higher adjuvanticity than 200 μg of sHZ. This result implied that sHZ enhanced the immunogenicity of SV in a dose-dependent
manner in ferrets. It is reported that the ferret model can evaluate not only the efficacy of vaccine but also the pyrogenicity of immunostimulatory agents like TLR ligands (e.g. TLR7/8 agonist R848) and virion components, and non-pyrogenicity of SV [17] and [18] To evaluate the pyrogenicity of sHZ after the first immunization, ferrets were immunized with saline or SV/sHZ (800 μg), and the body temperatures of ferrets were monitored continuously. The results showed that sHZ did not enhance the body temperature after immunization, INK1197 clinical trial and no difference was observed in body temperature between the SV/sHZ
and the saline groups, suggesting that sHZ does not have the potential to induce a pyrogenic reaction in ferrets (Fig. 3). Having observed such potent adjuvanticity without pyrogenicity of sHZ in ferrets, we next evaluated the contribution of sHZ-adjuvanted SP600125 chemical structure SV vaccine to its protective efficacy. On day 7 after the second immunization, the ferrets were intranasally infected with B/Osaka/32/2009, and viral titers in nasal cavities were measured daily after infection. On day 2 after infection, each viral titer of two groups SV/sHZ (200 μg) and SV/sHZ (800 μg) was significantly lower than that of the SV group (p < 0.01 and <0.001, respectively) ( Fig. 4A). Each viral titer AUC of SV/sHZ (200 μg and 800 μg) groups was significantly lower than that of the SV group (p < 0.01) ( Fig. 4C). The body temperature Bumetanide changes of ferrets were monitored from 2 days before to 5 days after infection. Comparing the SV group with the SV/sHZ group showed that the elevations of body temperature were suppressed in all SV/sHZ groups in a dose-dependent manner (Fig. 4B). Moreover, body temperature change AUCs of all SV/sHZ groups were lower than that of the SV vaccine group (Fig. 4D). Vaccination is the primary strategy to prevent influenza infection [19]. The efficacy of influenza vaccine in young and healthy adults is estimated to be 70–90%, but that in the elderly is lower at 17–53% [7]. Dose escalation
of antigen has been examined to enhance the efficacy of vaccine for the elderly [20]. However, this is not a realistic approach without improvement of the manufacturing plants or manufacturing systems. As an alternative strategy, the use of adjuvant may help overcome these issues by enhancing the immunogenicity of influenza vaccine. In the present study, sHZ enhanced the immunogenicity of SV and consequently elevated its protective efficacy against virus infection in the ferret model, which has been shown to reflect influenza symptoms and protective immune responses to influenza infection in humans [21]. In particular, SV/sHZ (800 μg) strongly suppressed the viral titer below the detection limit and did not cause pyrogenic reaction after immunization.