A new material developed at Cornell could significantly improve the delivery and effectiveness of mRNA vaccines - used to fight COVID-19 - by replacing a commonly used ingredient that may trigger unwanted immune responses in some people.
Thanks to their ability to train cells to produce virus-killing proteins, mRNA vaccines have gained popularity over the last five years for their success in reducing the severity of COVID-19 infection. One method for delivering the mRNA to cells is by packaging it inside fatty spheres, called lipid nanoparticles, that protect it from being degraded. However, a common component of lipid nanoparticles called poly-ethylene glycol (PEG) can provoke immune responses in some individuals, leading researchers to search for more biocompatible materials.
Shaoyi Jiang, Ph.D. '93, the Robert Langer '70 Family and Friends Professor in the Meinig School of Biomedical Engineering and professor in the R.F. Smith School of Chemical and Biomolecular Engineering, Cornell Engineering, is working to replace the PEG component of lipid nanoparticles with a more adaptable and stealthy option. The research is detailed May 29 in the journal Nature Materials.
The delivery vehicle for an mRNA vaccine needs to strike a Goldilocks balance - stable enough to protect the mRNA, yet labile enough to release it inside cells, and shielded enough to evade immune surveillance, but not so hidden that it hinders cellular uptake. PEG does the job, but presents some unintended side effects in a small subset of individuals.
"The human body is mostly water, so if you insert something with exposed hydrophobic moieties, like PEG, into our blood stream, our immune surveillance system says, 'Hey, that's a foreign material,' and will generate an antibody to destroy it," said Jiang. This environment makes adverse responses to a vaccine more likely and thus makes it harder for the vaccine to do its job.
Most people's immune systems are already primed to fight PEG. Prior research shows that a majority of people have anti-PEG antibodies "from people being exposed to PEG in so many commercial products like shampoo and toothpaste," said Jiang, adding that this widespread exposure may explain why the body is so quick to flag PEG as a threat.
To solve this, Jiang has developed lipid nanoparticles that use a zwitterionic polymer, a crucial alternative to PEG, enhancing the performance and biocompatibility of the system. Due to the super-hydrophilic, or water-loving, nature of zwitterions, this material is able to blend into the body and deliver the mRNA more easily. This specific naturally derived material, called poly (carboxybetaine) (PCB), has perfect balance of stealth and stability. In his recent paper, Jiang found that replacing PEG with PCB in lipid nanoparticle results in highly effective mRNA vaccines that do not adversely trigger the body's immune system.
Jiang is working with Weill Cornell Medicine, Houston Methodist Cancer Center, the Hospital for Sick Children in Toronto, and the National Cancer Institute to move this discovery toward clinical applications, specifically in the development of mRNA-based cancer vaccines. The zwitterionic nanoparticles help sneak the vaccines past the body's immune surveillance so that it induces antigen-specific immune responses while minimizing undesired immune activation.
"With a virus like COVID-19, you only need a tiny vaccine dose and our immune system will respond. But for a cancer vaccine, the tumor environment suppresses the immune system, so you need a much higher dose to be effective," said Jiang. "If a patient has a minor problem because of the PEG, the issue will be amplified with a higher dose."
Jiang has had success using this material to coat and protect a number of different medical and nonmedical products and lauds its ability to work into many different water-based environments.
"To the body, the material looks like water, and for this reason it has been successful in a number of applications, from medical devices such as implants and other drugs, and even on the bulkheads of Navy ships in contact with water."
The research was supported in part by the National Institute of Allergy and Infectious Diseases and the National Cancer Institute, both part of the National Institutes of Health.
Melia Matthews is a freelance writer for Cornell Engineering.
