In our daily lives, vaccination stands as a crucial method for preventing external diseases and fortifying the immune system. Vaccines stimulate the body's immune system to generate antibodies, initiating a robust defense against invading viruses.
However, vaccines are not universally effective, especially considering the continuous mutations in viruses such as the seasonal flu virus or recent variants of the COVID-19 virus like Delta and Omicron. Mutations, particularly in spike proteins, can significantly reduce the effectiveness of vaccines.
Addressing this challenge, Dr. Yan Qin and Dr. Wei Luo, postdocs from Stanford University (now an Assistant Professor at Indiana University), collaborated to develop a broad-spectrum and long-lasting vaccine. They engineered cell-adjuvant-loaded nanoparticle TLR7-NP, featuring adjustable drug loading, a narrow size distribution, controlled release kinetics, enhanced lymph node targeting, sustained activation of immune cells, and improved broad immune responses against multiple virus variants.
This research holds significant importance in developing widespread, potent, and durable immune-protective vaccines. It not only aids in controlling current disease outbreaks but also provides effective defense against potential viral pandemics in the future.
While most current research focuses on designing the antigenic components of vaccines, which involves complex protein engineering and lengthy cycles, this study employs an engineering approach to modify the adjuvant portion of the vaccine. By altering the physical and chemical properties of the adjuvant, the researchers artificially control the immune response induced by the vaccine, leading to the production of effective antibodies.
In addition, nanoparticles have potential applications and various advantages in the fields of diagnosis and treatment. For example, they can be modified with ligands to improve targeting and protect their cargo from deactivation or degradation during drug delivery. However, when synthetically engineered nanoparticles are introduced for in vivo applications, they are easily recognized as invaders by the innate immune system and can be swiftly cleared by the reticuloendothelial system (RES), leading to a rapid loss of their functionality.
Additionally, nanoparticles demonstrate potential applications and advantages in diagnosis and treatment. Extensive research on coating nanoparticles with cell membranes (CM-NPs) has been conducted to overcome limitations. These biomimetic nanoparticles leverage the multifunctionality and complexity of cell membranes, along with the physical and chemical properties of nanocarriers. The transfer of the entire cell membrane onto the surface of nanoparticles, including surface components relevant for immune evasion and targeting, makes CM-NPs an ideal strategy.
Moreover, because cell membrane coating closely resembles the structure and function of host cells, it can express specific markers that aid in proper nanoparticle delivery. These unique features of our cell membrane coating technology make it a promising strategy for various biomedical applications.
