Outer Membrane Vesicles of Bordetella pertussis encapsulated into sodium alginate nanoparticles as novel vaccine delivery system

Background: Outer membrane vesicles (OMVs) release from Gram-negative bacteria and are interesting alternatives that can replace those vaccines that contain naturally incorporated bacterial surface antigens, lipopolysaccharides (LPS) and outer membrane proteins (OMPs). Nanoparticles can be used to encapsulate vesicles for slow release and prevent macromolecular degradation. Objective: Therefore, encapsulation of OMVs of B. pertussis into sodium alginate nanoparticles was the main aim of the current study. Method: The OMVs of B. pertussis extracted and characterized by particle sizer, electron microscopy, SDSPAGE and Western blot assays. The extracted OMVs were encapsulated in sodium alginate nanoparticles (OMV-NP) using unique gelation process and injected into BALB/c mice. Immunogenicity indices such as different classes of antibodies and interleukins related to different T cell lines were evaluated in immunized mice by ELISA. The respiratory challenge was evaluated in the groups of mice. The existence of pertussis toxin (PTX), filamentous haemagglutinin (FHA) and PRN (pertactin) in B. pertussis OMVs was verified using SDS-PAGE and Western blot analysis. Results: TEM electron microscopy showed the size of these OMVs to be around 20-80 nm. The OMVs with appropriate quality were encapsulated into sodium alginate nanoparticles (OMV-NP), and the final size was about 500 nm after encapsulation. Immunity indices were significantly higher in the OMV-NP receiving group. In challenge tests, the OMV-NP vaccine was able to show the highest rate of lung clearance compared to the control groups (OMV and wPV) at the lowest injection dose. Conclusion: The results indicate the potential of OMV-NP as a novel vaccine delivery system.

Chemical Conjugation Strategies for the Development of Protein-Based Subunit Nanovaccines

The production of subunit nanovaccines relies heavily on the development of a vaccine delivery system that is safe and efficient at delivering antigens to the target site. Nanoparticles have been extensively investigated for vaccine delivery over the years, as they often possess self-adjuvanting properties. The conjugation of antigens to nanoparticles by covalent bonds ensures co-delivery of these components to the same subset of immune cells in order to trigger the desired immune responses. Herein, we review covalent conjugation strategies for grafting protein or peptide antigens onto other molecules or nanoparticles to obtain subunit nanovaccines. We also discuss the advantages of chemical conjugation in developing these vaccines.

A Thermostable, Flexible RNA Vaccine Delivery Platform for Pandemic Response

Current RNA vaccines against SARS-CoV-2 are limited by instability of both the RNA and the lipid nanoparticle delivery system, requiring storage at −20°C or −70°C and compromising universally accessible vaccine distribution. This study demonstrates the thermostability and adaptability of a nanostructured lipid carrier (NLC) RNA vaccine delivery system for use in pandemic preparedness and pandemic response. Liquid NLC is stable at refrigerated temperatures for ≥ 1 year, enabling stockpiling and rapid deployment by point-of-care mixing with any vaccine RNA. Alternatively, NLC complexed with RNA may be readily lyophilized and stored at room temperature for ≥ 8 months or refrigerated temperature for ≥ 21 months. This thermostable RNA vaccine platform could significantly improve distribution of current and future pandemic response vaccines, particularly in low-resource settings.One Sentence SummaryAn RNA vaccine delivery system stable at room temperature for 8+ months and refrigerated for 21+ months.

Solid Lipid Nanoparticle Carrier Platform Containing Synthetic TLR4 Agonist Mediates Non-Viral DNA Vaccine Delivery

There is a growing demand for better delivery systems to improve the stability and efficacy of DNA vaccines. Here we report the synthesis of a non-viral DNA vaccine delivery system using a novel adjuvanted solid lipid nanoparticle (SLN-A) platform as a carrier for a DNA vaccine candidate encoding the Urease alpha (UreA) antigen from Helicobacter pylori. Cationic SLN-A particles containing monophosphoryl lipid A (adjuvant) were synthesised by a modified solvent-emulsification method and were investigated for their morphology, zeta potential and in vitro transfection capacity. Particles were found to bind plasmid DNA to form lipoplexes, which were characterised by electron microscopy, dynamic light scattering and fluorescence microscopy. Cellular uptake studies confirmed particle uptake within 3 h, and intracellular localisation within endosomal compartments. In vitro studies further confirmed the ability of SLN-A particles to stimulate expression of pro-inflammatory cytokine tumor necrosis factor alpha (TNF-α) in human macrophage-like Tohoku Hospital Pediatrics-1 (THP-1) cells. Lipoplexes were found to be biocompatible and could be efficiently transfected in murine immune cells for expression of recombinant H. pylori antigen Urease A, demonstrating their potential as a DNA vaccine delivery system.