Scaleable production of highly loaded protein nanoparticles for immune modulation

Abstract

Immune modulation and  desensitization is a growing field of research and clinical investigation that requires precise delivery of antigens to immune system cells. Nanoparticles (NPs) have emerged as excellent candidates for antigen delivery, particularly in immune desensitization applications. NP-encapsulated protein antigens enable the delivery of protein and co-encapsulated adjuvant to antigen-presenting cells without systemic exposure and allergic response. Here, we show a method for producing poly(lactide-co-glycolide) (PLG) NPs in an efficient, high-yield, and large-scale inhomogeneous precipitation process. The process enables the production of compositionally complex PLG NPs containing protein while also incorporating DNA and E. coli phospholipids as integral adjuvants in the NP vehicle. Orally delivered PLG NPs activate the murine immune system, and encapsulated peanut allergen protein elicits approximately 10-fold lower levels of basophil activation than does unencapsulated protein in basophils isolated from peanut-allergic patients. This efficacy and safety evidence makes these PLG NPs excellent candidates for clinical applications. Protein-loaded nanoparticles are important for immunomodulatory applications. Here, an efficient method for producing protein-containing nanoparticles at large scale is developed which overcomes prior limitations on the use of poly(lactide-co-glycolide) nanoparticles.