免疫系统
抗原
材料科学
表面工程
免疫学
纳米技术
生物
作者
Zhihui Liang,Yun Yang,Ge Yu,Haoru Zhu,Xinyu Xia,Chen Chen,Duo Fu,Min Li,Gang Cheng,Changying Xue,Li Shi,Hao Zeng,Bingbing Sun
出处
期刊:Biomaterials
[Elsevier]
日期:2021-06-07
卷期号:275: 120960-120960
被引量:40
标识
DOI:10.1016/j.biomaterials.2021.120960
摘要
Aluminum phosphate adjuvants play a critical role in human inactivated and subunit prophylactic vaccines. However, a major challenge is that the underlying mechanism of immune stimulation remains poorly understood, which impedes the further optimal design and application of more effective adjuvants in vaccine formulations. To address this, a library of amorphous aluminum hydroxyphosphate nanoparticles (AAHPs) is engineered with defined surface properties to explore the specific mechanism of adjuvanticity at the nano-bio interface. The results demonstrate that AAHPs could induce cell membrane perturbation and downstream inflammatory responses, with positively-charged particles showing the most significantly enhanced immunostimulation potentials compared to the neutral or negatively-charged particles. In a vaccine using Staphylococcus aureus (S. aureus) recombinant protein as antigens, the positively-charged particles elicit long-lasting and enhanced humoral immunity, and provide protection in S. aureus sepsis mice models. In addition, when formulated with human papillomavirus type 18 virus-like particles, it is demonstrated that particles with positive charges outperform in promoting serum antigen-specific antibody productions. This study shows that engineering AAHPs with well-controlled physicochemical properties enable the establishment of a structure-activity relationship that is critical to instruct the design of suitable engineered nanomaterial-based adjuvants within vaccine formulations for the benefits of human health.
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