Formulation Design, Optimization and In Vivo Evaluations of an α-Tocopherol-Containing Self-Emulsified Adjuvant System using Inactivated Influenza Vaccine.

α-Tocopherol has been used as an immune supplement in humans, as an emulsion adjuvant component in several veterinary vaccines as well as an immunomodulatory component of AS03, an emulsion adjuvant that was used in an H1N1 pandemic vaccine (Pandemrix). AS03 is manufactured using microfluidization and high-pressure homogenization. Such high energy and complex manufacturing processes make it difficult and expensive to produce emulsion adjuvants on a large scale, especially in developing countries. In this study we have explored simpler, comparatively inexpensive methods, to formulate emulsion adjuvants containing α-tocopherol, that have the potential to be made in any well-established scale-up facility. This might facilitate producing and stock-piling adjuvant doses and therefore aide in pandemic preparedness. We used design of experiment as a tool to explore incorporating α-tocopherol into self-emulsified systems containing squalene oil and polysorbate 80. We created novel self-emulsified adjuvant systems (SE-AS) and evaluated their potency in vivo in BALB/c mice with inactivated quadrivalent influenza vaccine (QIV) and tested the cellular and humoral immune responses against the four vaccine strains.

Low hemagglutinin antigen dose influenza vaccines adjuvanted with AS03 alter the long-term immune responses in BALB/c mice.

We investigated the long-term immune profiles of dose-sparing, AS03-adjuvanted vaccines compared to a traditional high-dose, unadjuvated influenza vaccine formulation. BALB/c mice received 2 IM injections of influenza A/Uruguay/716/2007 (H3N2) split vaccine antigen: high-dose (HD) (3 µg hemagglutinin (HA)/dose) or low-dose (LD) formulations (0.03 µg or 0.003 µg HA) with AS03 and were followed to 34 weeks post-boost (pb). We examined serologic responses, spleen and bone marrow (BM) HA-specific antibody-secreting cells (ASCs) by ELISpot, influenza-specific cytokine/chemokine production in re-stimulated splenocytes by multiplex ELISA, and antigen-specific CD4+ T cells that express cytokines (IL-2, IFNγ, TNFα and IL-5) by flow cytometry. All formulations elicited robust serum antibody titers that persisted for at least 34 weeks. The number of antigen-specific ASCs in the spleen and BM were higher in the 2 LD +AS03 groups, but despite having fewer ASCs, the average spot size in the HD-unadjuvanted group was larger at later time-points, suggesting greater antibody production per cell. Striking differences in the long-term profiles induced by the different vaccine formulations may contribute to these different ASC profiles. The HD-unadjuvanted vaccine elicited strong Th2 cytokines during the first 6 weeks pb but LD+AS03 groups generated broader, more durable responses at later timepoints. Finally, the 0.03 µg HA+AS03 group generated the greatest number of antigen-specific CD4+ T cells and the highest percentage of poly-functional cells that expressed 2 or more cytokines. Although all of the tested vaccines induced durable antibody responses, we show that different vaccine formulations (dose-sparing, adjuvant) generate distinct long-term immune profiles. Furthermore, our data suggest that the different profiles may be generated through unique mechanisms.

Comparison of AS03 and Alum on immune responses elicited by A/H3N2 split influenza vaccine in young, mature and aged BALB/c mice.

INTRODUCTION: There is great interest in developing more effective influenza vaccines for the elderly. Oil-in-water adjuvants can boost humoral responses to seasonal vaccines in elderly subjects but relatively little is known about their mechanism of action. METHODS: We compared humoral and cellular immune profiles in young adult (2 months), mature (11-12 months) or aged (16-17 month) female BALB/c mice following two doses of Alum or AS03-adjuvanted A/H3N2 split-virus antigen (A/Uruguay/716/2007) at 0.75 or 3 µg hemagglutinin (HA) per dose intramuscularly versus 3 µg HA without adjuvant. RESULTS: Overall, hemagglutination inhibition (HAI), microneutralization (MN) and end-point ELISA titres were higher in the young mice and when an adjuvant was used. Both adjuvants increased humoral responses in older animals but the highest titres across all groups were observed in the AS03-adjuvanted groups. Neither IgG avidity nor A/H3N2-specific splenocyte proliferation was influenced by age, antigen dose or adjuvant. In contrast, cytokine production by ex vivo-stimulated splenocytes differed widely between groups. Most cytokine levels in older mice vaccinated with antigen alone (3 µg HA/dose) were ≤ 50% of those in young animals. In young mice, cytokine levels increased modestly with Alum and significantly with AS03. Increases tended to be greatest at the lower antigen dose (0.75 µg versus 3 µg HA). In the older animals, Alum had little impact on cytokine production but responses in the AS03 groups paralleled those of the young mice (broad activation of Th1, Th2, and Th17-type cytokines) and the greatest increases were seen with the higher antigen dose (3 µg HA). CONCLUSIONS: In both young and aged mice, Alum and AS03 increased the magnitude of humoral and cellular responses to split influenza virus vaccination. Overall, these effects were most pronounced in the younger animals and the groups receiving AS03. These data support the use of oil-in-water adjuvants in influenza vaccines targeting the elderly.

AS03-adjuvanted H7N1 detergent-split virion vaccine is highly immunogenic in unprimed mice and induces cross-reactive antibodies to emerged H7N9 and additional H7 subtypes.

Avian H7 is one of several influenza A virus subtypes that have the potential to cause pandemics. Herein we describe preclinical results following administration of an investigational H7N1 inactivated detergent-split virion vaccine adjuvanted with the AS03 Adjuvant System. The adjuvanted H7N1 vaccine was highly immunogenic compared to the non-adjuvanted H7N1 vaccine in unprimed mice with less than 100ng of hemagglutinin antigen per dose. In addition, compared to the non-adjuvanted vaccine, the AS03-adjuvanted H7N1 vaccine also induced robust HI and VN antibody responses that cross-reacted with other H7 subtypes, including recently emerged H7N9 virus. These H7 data from the preclinical mouse model add to the existing H5 data to suggest that AS03 adjuvant technology may be generally effective for formulating antigen-sparing detergent-split virion vaccines against intrinsically sub-immunogenic avian influenza A virus subtypes.