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协同作用:疫苗抗原与佐剂之间的相互作用

Working together: interactions between vaccine antigens and adjuvants.

作者信息

Fox Christopher B, Kramer Ryan M, Barnes V Lucien, Dowling Quinton M, Vedvick Thomas S

机构信息

IDRI, 1124 Columbia Street, Ste 400, Seattle, WA 98104, USA.

IDRI, Seattle, WA USA.

出版信息

Ther Adv Vaccines. 2013 May;1(1):7-20. doi: 10.1177/2051013613480144.

DOI:10.1177/2051013613480144
PMID:24757512
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3967670/
Abstract

The development of vaccines containing adjuvants has the potential to enhance antibody and cellular immune responses, broaden protective immunity against heterogeneous pathogen strains, enable antigen dose sparing, and facilitate efficacy in immunocompromised populations. Nevertheless, the structural interplay between antigen and adjuvant components is often not taken into account in the published literature. Interactions between antigen and adjuvant formulations should be well characterized to enable optimum vaccine stability and efficacy. This review focuses on the importance of characterizing antigen-adjuvant interactions by summarizing findings involving widely used adjuvant formulation platforms, such as aluminum salts, emulsions, lipid vesicles, and polymer-based particles. Emphasis is placed on the physicochemical basis of antigen-adjuvant associations and the appropriate analytical tools for their characterization, as well as discussing the effects of these interactions on vaccine potency.

摘要

含佐剂疫苗的研发有潜力增强抗体和细胞免疫反应,扩大针对异源病原体菌株的保护性免疫,实现抗原剂量节省,并提高免疫功能低下人群的疫苗效力。然而,已发表的文献中往往没有考虑抗原和佐剂成分之间的结构相互作用。抗原与佐剂配方之间的相互作用应得到充分表征,以确保疫苗具有最佳稳定性和效力。本综述通过总结涉及广泛使用的佐剂配方平台(如铝盐、乳剂、脂质体和聚合物颗粒)的研究结果,重点阐述了表征抗原-佐剂相互作用的重要性。重点介绍了抗原-佐剂结合的物理化学基础及其表征所需的适当分析工具,并讨论了这些相互作用对疫苗效力的影响。

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