Nanoemulsion is an effective antimicrobial for methicillin-resistant Staphylococcus aureus in infected wounds.

AIM: To develop NB-201, a nanoemulsion compound, as a novel microbicidal agent against methicillin-resistant Staphylococcus aureus (MRSA) infection, which is a common threat to public health but with limited therapeutic options. MATERIALS & METHODS: NB-201 was tested in in vitro and in vivo murine and porcine models infected with MRSA. RESULTS: Topical treatment of MRSA-infected wounds with NB-201 significantly decreased bacterial load and had no toxic effects on healthy skin tissues. NB-201 attenuated neutrophil sequestration in MRSA-infected wounds and inhibited epidermal and deep dermal inflammation. The levels of proinflammatory cytokines were reduced in NB-201-treated MRSA-infected wounds. CONCLUSION: NB-201 can greatly reduce inflammation characteristic of infected wounds and has antimicrobial activity that effectively kills MRSA regardless of the genetic basis of antibiotic resistance.

Nanoemulsion mucosal adjuvant uniquely activates cytokine production by nasal ciliated epithelium and induces dendritic cell trafficking.

While the nasal mucosa is a potentially useful site for human immunization, toxin-based nasal adjuvants are generally unsafe and less effective in humans. Safe mucosal adjuvants that activate protective immunity via mucosal administration are highly dependent on barrier antigen sampling by epithelial and DCs. Here, we demonstrate that protein antigens formulated in unique oil-in-water nanoemulsions (NEs) result in distinctive transcellular antigen uptake in ciliated nasal epithelial cells, leading to delivery into nasal associated lymphoid tissue. NE formulation also enhances MHC class II expression in epithelial cells and DC activation/trafficking to regional lymphoid tissues in mice. These materials appear to induce local epithelial cell apoptosis and heterogeneous cytokine production by mucosal epithelial cells and mixed nasal tissues, including G-CSF, GM-CSF, IL-1a, IL-1b, IL-5, IL-6, IL-12, IP-10, KC, MIP-1a, TGF-ß, and TSLP. This is the first observation of a nasal adjuvant that activates calreticulin-associated apoptosis of ciliated nasal epithelial cells to generate broad cytokine/chemokine responses in mucosal tissue.

Induction of immune tolerance in mice with a novel mucosal nanoemulsion adjuvant and self-antigen.

AIM: The aim of this study was to investigate the impact of a novel nanoemulsion (NE) adjuvant, a soybean oil emulsion, on autoimmune response. To this end, we used murine thyroglobulin (mTg)-induced experimental autoimmune thyroiditis in mice as a study model. MATERIALS & METHODS: Mice received NE or NE + mTg by nasal delivery. At 1 week after the second nasal delivery of NE with or without mTg, all mice were immunized with mTg and lipopolysaccharides to induce experimental autoimmune thyroiditis. RESULTS: Compared with controls, mTg-NE-treated mice had much more antigens accumulated in the nasal passage and thymus and developed a milder form of thyroiditis. This was accompanied by an increase in IL-10, IL-17 and reduced IFN-γ. The production of anti-mTg antibodies was significantly decreased in mTg-NE-treated mice. The percentage of Tregs in cervical lymph nodes was higher in mTg-NE-treated mice than NE-treated mice. Furthermore, Foxp3 and TGF-ß levels were prominently enhanced in mTg-NE-treated mice. CONCLUSION: This study indicates that a low dose of mTg in NE can significantly enhance antigen uptake and Tregs, resulting in inhibition of experimental autoimmune thyroiditis development.