Conjunctival vaccination against Brucella ovis in mice with mannosylated nanoparticles.

The use of sub-unit vaccines can solve some drawbacks associated with traditional attenuated or inactivated ones. However, in order to improve their immunogenicity, these vaccines needs to be associated to an appropriate adjuvant which, adequately selected, may also offer an alternative pathway for administration. The aim of this work was to evaluate the protection offered by the hot saline complex extracted from Brucella ovis (HS) encapsulated in mannosylated nanoparticles (MAN-NP-HS) when instilled conjunctivally in mice. Nanoparticles displayed a size of 300 nm and the antigen loading was close to 30 µg per mg nanoparticle. Importantly, encapsulated HS maintained its protein profile, structural integrity and antigenicity during and after the preparative process of nanoparticles. The ocular immunization was performed on BALB/c mice. Eight weeks after vaccination animals were challenged with B. ovis, and 3 weeks later, were slaughtered for bacteriological examinations. Animals immunized with MAN-NP-HS displayed a 3-log reduction in spleen CFU compared with unvaccinated animals. This degree of protection was significantly higher than that observed for the commercial vaccine (Rev1) subcutaneously administered. Interestingly, the mucosal IgA response induced by MAN-NP-HS was found to be much more intense than that offered by Rev1 and prolonged in time. Furthermore, the elicited IL-2, IL-4 and γ-IFN levels showed good correlation with the degree of protection. On the other hand, biodistribution studies in animals were performed with nanoparticles labelled with either (99m)technetium or rhodamine B isothiocyanate. The biodistribution revealed that, after instillation, MAN-NP-HS moved from the palpebral area to the nasal region and, the gastrointestinal tract. This profile of distribution was different to that observed for free (99m)TcO4⁻ colloids, which remained for at least 24h in the site of administration. In summary, mannosylated nanoparticles appear to be a safe and suitable adjuvant for conjunctival vaccination.

Evaluation of particulate acellular vaccines against Brucella ovis infection in rams.

The attenuated Brucella melitensis Rev 1 vaccine, used against brucellosis infection, interferes with serological diagnosis tests, may induce abortions in pregnant animals, and may infect humans. In order to overcome these drawbacks, we developed acellular vaccines based on a Brucella ovis antigenic complex (HS) containing outer membrane proteins and R-LPS entrapped in poly(anhydride) conventional and mannosylated nanoparticles (NP-HS and MAN-NP-HS) or in poly(epsilon-caprolactone) microparticles (HS-PEC) as antigen delivery systems and immunoadjuvants. Brucellosis free rams were vaccinated subcutaneously with a single dose of particles containing 3mg of HS, and challenged 6 months thereafter. Protection was evaluated by clinical, bacteriological and serological examinations, in comparison with non-vaccinated control rams. HS-PEC vaccine induced protection (7 out of 13 animals were infected) equivalent to that induced by the reference Rev 1 vaccine (8/14). In contrast, animals immunized with NP-HS were not protected, showing similar results to that obtained in the control unvaccinated rams. Furthermore HS-PEC vaccine did not interfere against B. melitensis serodiagnostic tests. In summary, HS-PEC microparticles could be used as a safe and effective vaccine against brucellosis in rams.

Design and influence of gamma-irradiation on the biopharmaceutical properties of nanoparticles containing an antigenic complex from Brucella ovis.

Despite vaccination campaigns, brucellosis is still one of the most common bacterial zoonosis in the world. This work describes the development of a novel formulation strategy to the delivery of the Brucella ovis antigenic extract (HS) into ovine mucosal surfaces. Thus, HS was entrapped in conventional and mannosylated poly(anhydride) nanoparticles by the solvent displacement method, and the resulting nanosystems were gamma-irradiated to accomplish the sterilization required for the ophthalmic administration route. Sterilization, at either 10 kGy or 25 kGy, did not modify the size, morphology and antigen content of the nanoparticles. Similarly, the integrity and antigenicity of the entrapped antigen were not affected by gamma-irradiation. The 25 kGy gamma-irradiation dose seemed to influence negatively the HS release from the carriers. However, and in accordance with the Pearson's correlation, all the release patterns followed a similar tendency. Furthermore, the stability of the vaccine systems on lachrymal and nasal ovine fluids, showed that gamma-irradiation had no significant effects on the vaccine systems. Since all the vaccine systems accomplished the pharmacopoeial biological tests required for gamma-irradiation doses under 25 kGy, these results are highly suggestive for the use of HS loaded poly(anhydride) nanoparticles as an efficient vaccine delivery system for brucellosis immunoprophylaxis, especially for ophthalmic administration.