期刊
ACTA BIOMATERIALIA
卷 68, 期 -, 页码 168-177出版社
ELSEVIER SCI LTD
DOI: 10.1016/j.actbio.2017.12.040
关键词
Poly(beta-amino ester); Macrophage and dendritic cell; Vaccine and immunotherapy; Microparticle and nanoparticle; Immune response and inflammation
资金
- NSF CAREER Award [1351688]
- Alliance for Cancer Gene Therapy [15051543]
- National Cancer Institute
- University of Maryland
- Div Of Chem, Bioeng, Env, & Transp Sys
- Directorate For Engineering [1351688] Funding Source: National Science Foundation
Nucleic acid delivery vehicles are poised to play an important role in delivering gene therapy for vaccines and immunotherapies, and in delivering nucleic acid based adjuvants. A number of common polymeric delivery vehicles used in nucleic acid delivery have recently been shown to interact with immune cells and directly stimulate immunogenic responses, particularly in particle form. Poly(beta-amino esters) were designed for nucleic acid delivery and have demonstrated promising performance in a number of vaccine and therapeutic studies. Yet, little work has characterized the mechanisms by which these polymers activate immune cells. Here we demonstrate that a poly(beta-amino ester) activates antigen presenting cells in soluble and particulate forms, and that these effects are independent of TLR signaling pathways. Moreover, we show the polymers induce activation independent of NF-kappa B signaling, but do activate IRF, an important innate inflammatory pathway. New knowledge linking physicochemical features of poly(beta-amino esters) or other polymeric carriers to inflammatory mechanisms could support more rational design approaches for vaccines and immunotherapies harnessing these materials. Significance Statement The last several years have brought exciting work exploring biomaterials as delivery vehicles for immunotherapies, vaccines, and gene therapies. However, a gap remains between the striking finding that many biomaterials exhibit intrinsic immunogenic features, and the specific structural properties that drive these responses. The results in the current study indicate PBAEs cause macrophage activation by pathways that are distinct from pathways activated by common vaccine and immunotherapies components, such as toll-like receptor agonists. Thus, the work reveals new mechanistic details that can be exploited in investigating other materials, and to support more rational design of future biomaterial vaccines and immunotherapy carriers. Published by Elsevier Ltd on behalf of Acta Materialia Inc.
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