Aluminum-based metal-organic framework nanoparticles as pulmonary vaccine adjuvants.

The adoption of pulmonary vaccines to advantageously provide superior local mucosal protection against aerosolized pathogens has been faced with numerous logistical and practical challenges. One of these persistent challenges is the lack of effective vaccine adjuvants that could be well tolerated through the inhaled route of administration. Despite its widespread use as a vaccine adjuvant, aluminum salts (alum) are not well tolerated in the lung. To address this issue, we evaluated the use of porous aluminum (Al)-based metal-organic framework (MOF) nanoparticles (NPs) as inhalable adjuvants. We evaluate a suite of Al-based MOF NPs alongside alum including DUT-4, DUT-5, MIL-53 (Al), and MIL-101-NH2 (Al). As synthesized, MOF NPs ranged between ~ 200 nm and 1 µm in diameter, with the larger diameter MOFs matching those of commercial alum. In vitro examination of co-stimulatory markers revealed that the Al-based MOF NPs activated antigen presenting cells more effectively than alum. Similar results were found during in vivo immunizations utilizing ovalbumin (OVA) as a model antigen, resulting in robust mucosal humoral responses for all Al MOFs tested. In particular, DUT-5 was able to elicit mucosal OVA-specific IgA antibodies that were significantly higher than the other MOFs or alum dosed at the same NP mass. DUT-5 also was uniquely able to generate detectable IgG2a titers, indicative of a cellular immune response and also had superior performance relative to alum at equivalent Al dosed in a reduced dosage vaccination study. All MOF NPs tested were generally well-tolerated in the lung, with only acute levels of cellular infiltrates detected and no Al accumulation; Al content was largely cleared from the lung and other organs at 28 days despite the two-dose regime. Furthermore, all MOF NPs exhibited mass median aerodynamic diameters (MMADs) of ~ 1.5-2.5 µm when dispersed from a generic dry powder inhaler, ideal for efficient lung deposition. While further work is needed, these results demonstrate the great potential for use of Al-based MOFs for pulmonary vaccination as novel inhalable adjuvants.

Degradation Profiles of Poly(ethylene glycol) diacrylate (PEGDA)-based hydrogel nanoparticles.

Hydrogel nanoparticles (also known as nanogels) have been utilized for a wide range of applications including analytics, sensors, drug delivery, immune engineering, and biotechnology. While these types of nanoparticles can be characterized using standard colloidal characterization techniques, degradation profiles typically must be inferred from those of bulk gels with the same formulation, typically by applying swelling ratios and rheological measurements that tend to severely underestimate nanoparticle degradation rates. Herein, we present an analysis of the degradation via ester hydrolysis of poly(ethylene glycol) diacrylate (PEGDA)-based hydrogel nanoparticles in water, varied pH conditions, and redox environments. We perform this characterization using thermogravimetric analysis and mass spectrometry to analyze rates of degradation and products released, respectively, and compare results to those for equivalent bulk gel formulations. Our findings show that PEGDA-based nanoparticles display significant mass loss over time accompanied by negligible changes in hydrodynamic diameter, indicating a bulk mode of degradation. Nanoparticle mass loss occurs at a much higher rate than for bulk gels under comparable incubation conditions, confirming that bulk gel degradation serves as a poor surrogate for nanoparticle degradation. We further demonstrate that the incorporation of other diacrylate-based co-monomers drastically accelerates nanoparticle degradation rates. Through formulation considerations of co-monomer content and weight percent of PEGDA, we demonstrate the ability to tune the degradation rates of PEGDA-based nanoparticles on a range of hours to weeks. These findings highlight critical design considerations for enhancing the tunability and utility of PEGDA hydrogel nanoparticles and introduce a rigorous framework for the characterization of nanogel degradation.