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Researchers breathe new life into lung repair

By: Nathi Magubane Date: Feb 1, 2024
Artist's interpretation of human lungs and a virus.
Respiratory diseases like influenza and COVID-19 drive inflammatory responses that can cause long-term damage to the lungs and can be difficult to treat. Now, by using techniques that deliver mRNA via lipid nanoparticles, researchers led by Andrew Vaughan of the School of Veterinary Medicine were able to greatly enhance modes of repair for damaged blood vessels in the lung, leading to improved oxygen saturation. (Image: iStock/Mohammed Haneefa Nizamudeen)

In the human body, the lungs and their vasculature can be likened to a building with an intricate plumbing system. The lungs’ blood vessels are the pipes essential for transporting blood and nutrients for oxygen delivery and carbon dioxide removal. Much like how pipes can get rusty or clogged, disrupting normal water flow, damage from respiratory viruses, like SARS-CoV-2 or influenza, can interfere with this “plumbing system.”

In a recent study, researchers looked at the critical role of vascular endothelial cells in lung repair. Their work, published in Science Translational Medicine, was led by Andrew Vaughan of the University of Pennsylvania’s School of Veterinary Medicine and shows that, by using techniques that deliver vascular endothelial growth factor alpha (VEGFA) via lipid nanoparticles (LNPs), that they were able to greatly enhance modes of repair for these damaged blood vessels, much like how plumbers patch sections of broken pipes and add new ones.

“While our lab and others have previously shown that endothelial cells are among the unsung heroes in repairing the lungs after viral infections like the flu, this tells us more about the story and sheds light on the molecular mechanisms at play,” says Vaughan, assistant professor of biomedical sciences at Penn Vet. “Here we’ve identified and isolated pathways involved in repairing this tissue, delivered mRNA to endothelial cells, and consequently observed enhanced recovery of the damaged tissue. These findings hint at a more efficient way to promote lung recovery after diseases like COVID-19.”

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