A Formulated TLR7/8 Agonist is a Flexible, Highly Potent and Effective Adjuvant for Pandemic Influenza Vaccines.

Since 1997, highly pathogenic avian influenza viruses of the H5N1 subtype have been transmitted from avian hosts to humans. The severity of H5N1 infection in humans, as well as the sporadic nature of H5N1 outbreaks, both geographically and temporally, make generation of an effective vaccine a global public health priority. An effective H5N1 vaccine must ultimately provide protection against viruses from diverse clades. Toll-like receptor (TLR) agonist adjuvant formulations have a demonstrated ability to broaden H5N1 vaccine responses in pre-clinical models. However, many of these agonist molecules have proven difficult to develop clinically. Here, we describe comprehensive adjuvant formulation development of the imidazoquinoline TLR-7/8 agonist 3M-052, in combination with H5N1 hemagglutinin (HA) based antigens. We find that 3M-052 in multiple formulations protects both mice and ferrets from lethal H5N1 homologous virus challenge. Furthermore, we conclusively demonstrate the ability of 3M-052 adjuvant formulations to broaden responses to H5N1 HA based antigens, and show that this broadening is functional using a heterologous lethal virus challenge in ferrets. Given the extensive clinical use of imidazoquinoline TLR agonists for other indications, these studies identify multiple adjuvant formulations which may be rapidly advanced into clinical trials in an H5N1 vaccine.

Adjuvanted pandemic influenza vaccine: variation of emulsion components affects stability, antigen structure, and vaccine efficacy.

BACKGROUND: Adjuvant formulations are critical components of modern vaccines based on recombinant proteins, which are often poorly immunogenic without additional immune stimulants. Oil-in-water emulsions comprise an advanced class of vaccine adjuvants that are components of approved seasonal and pandemic influenza vaccines. However, few reports have been published that systematically evaluate the in vitro stability and in vivo adjuvant effects of different emulsion components. OBJECTIVES: To evaluate distinct classes of surfactants, oils, and excipients, for their effects on emulsion particle size stability, antigen structural interactions, and in vivo activity when formulated with a recombinant H5N1 antigen. METHODS: Emulsions were manufactured by high pressure homogenization and characterized alone or in the presence of vaccine antigen by dynamic light scattering, zeta potential, viscosity, pH, hemolytic activity, electron microscopy, fluorescence spectroscopy, and SDS-PAGE. In vivo vaccine activity in the murine model was characterized by measuring antibody titers, antibody-secreting plasma cells, hemagglutination inhibition titers, and cytokine production. RESULTS: We demonstrate that surfactant class and presence of additional excipients are not critical for biological activity, whereas oil structure is crucial. Moreover, we report that simplified two-component emulsions appear more stable by particle size than more complex formulations.Finally, differences in antigen structural interactions with the various emulsions do not appear to correlate with in vivo activity. CONCLUSIONS: Oil-in-water emulsions can significantly enhance antibody and cellular immune responses to a pandemic influenza antigen. The dramatic differences in adjuvant activity between squalene-based emulsion and medium chain triglyceride-based emulsion are due principally to the biological activity of the oil composition rather than physical interactions of the antigen with the emulsion.

Physicochemical characterization and biological activity of synthetic TLR4 agonist formulations.

Immunostimulatory molecules such as monophosphoryl lipid A (MPL), a Toll-like receptor 4 (TLR4) agonist, can be formulated to enhance vaccine adjuvant effects and to promote a Th1-type immune response. This study compares the in vitro and in vivo potency of aqueous and emulsion formulations containing a synthetic MPL analogue. In addition, formulation structure and association of the synthetic TLR-4 agonist and antigen with the formulation are characterized using dynamic light scattering, zeta potential measurement, HPLC, and SDS-PAGE. The biological and biophysical effects of formulating the agonist with different oil and surfactant components from animal, plant, and synthetic sources are examined. These findings have important implications for the formulation of TLR4 agonists as well as the influence of formulation component substitution on adjuvant activity. The results indicate that (1) the agonist is associated with the oil droplets in emulsion formulations, (2) the emulsion formulations containing synthetic TLR4 agonist induce higher IgG2a/IgG1 antibody ratios than aqueous formulations or an emulsion formulation without the agonist, and (3) appropriate plant-derived components can be substituted for animal-derived components in oil-in-water emulsions without loss of biological activity.

Enhanced humoral and Type 1 cellular immune responses with Fluzone adjuvanted with a synthetic TLR4 agonist formulated in an emulsion.

Impairments in anti-influenza T helper 1 (Th1) responses are associated with greater risk of influenza-related mortality in the elderly. Addition of adjuvants to existing influenza vaccines could improve immune responses in the elderly. In this study, the activity of three adjuvants, an oil-in-water emulsion and a synthetic lipid A adjuvant formulated with or without the emulsion, is compared. Our results show that Fluzone combined with lipid A plus an emulsion effectively leads to greater vaccine-specific IgG2a and IgG titers, enhances hemagglutination-inhibition titers and induces Type 1 cytokine responses (IFN-gamma and IL-2) to each of the Fluzone components.