In vitro and in vivo investigation of thermosensitive chitosan hydrogels containing silica nanoparticles for vaccine delivery

Abstract

In this work silica nanoparticles (SNP) containing the model antigen ovalbumin (OVA) were incorporated into a thermosensitive chitosan hydrogel, and the resulting formulation investigated for its potential to act as a particulate sustained release vaccine delivery system. OVA-loaded SNP and chitosan hydrogels containing OVA-loaded SNP were prepared and characterised in vitro, and examined for their ability to elicit OVA-specific immune responses in vivo. Optimised SNP were found to be approximately 300 nm in size with a moderate level of heterogeneity, a highly negative zeta potential, and an entrapment efficiency of approximately 7%. A porous particulate structure was indicated both by electron microscopy and a rapid release of fluorescently-labelled OVA (FITC-OVA) from SNP. Following successful incorporation of SNP into chitosan hydrogels, the release of both soluble and SNP-associated antigen from gel systems was quantified. Approximately 16% of total protein was released in a particulate form over a 14-day period, while approximately 35% was released as soluble antigen. Gel-based systems containing SNP-associated or soluble antigen in the presence or absence of the adjuvant Quil A (QA) demonstrated an ability to stimulate both cell mediated and humoral immunity in vivo. Chitosan gels containing OVA-loaded SNP and the adjuvant QA showed a significantly greater ability to induce CD4 + T cell proliferation than chitosan gel containing soluble OVA and QA, indicating the future promise for such a system.