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How Specialized Cells Contribute to Blood Vessel Dysfunction

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OHSU researchers have uncovered how specialized cells surrounding small blood vessels, known as perivascular cells, contribute to blood vessel dysfunction in chronic diseases such as cancer, diabetes and fibrosis. The findings could change how these diseases are treated. Credit: OHSU/Christine Torres Hicks
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Researchers at Oregon Health & Science University have uncovered how specialized cells surrounding small blood vessels, known as perivascular cells, contribute to blood vessel dysfunction in chronic diseases such as cancer, diabetes and fibrosis. The findings, published today in Science Advances, could change how these diseases are treated.


The study, led by Luiz Bertassoni, D.D.S., Ph.D., founding director of the Knight Cancer Precision Biofabrication Hub and a professor at the OHSU Knight Cancer Institute and the OHSU School of Dentistry,  shows that perivascular cells sense changes in nearby tissues and send signals that disrupt blood vessel function, worsening disease progression.


Nearly a decade ago, Bertassoni and his team developed a method to 3D print blood vessels in the lab — a breakthrough recognized as one of the top scientific discoveries of the year by Discover magazine. Since then, they’ve focused on engineering blood vessels that better mimic those in the human body to study more complex diseases.


“Historically, endothelial cells lining blood vessels have been considered the main contributors of vascular disease,” Bertassoni said. “Our findings represent a paradigm shift, showing how perivascular cells, instead, act as important sentinels. They detect changes in tissues and coordinating vascular responses. This opens the door to entirely new treatment strategies.”


Cristiane Miranda Franca, D.D.S., Ph.D., the study’s lead author, is an assistant professor in the OHSU School of Dentistry and holds appointments with the OHSU Knight Cancer Precision Biofabrication Hub and Knight Cancer Institute’s Cancer Early Detection Advanced Research Center, or CEDAR.

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“The applications of this research are wide,” she said. “We’ve shown for the first time how perivascular cells trigger inflammation and signal blood vessel changes when surrounding tissues are altered.”


The study used an innovative “blood vessel on-a-chip” model developed by Christopher Chen, M.D., Ph.D., and his team from Boston University and the Wyss Institute at Harvard, who are collaborators on this project. By replicating conditions like tissue stiffening and scarring — common in aging, chronic diseases and cancer — the researchers discovered that perivascular cells drive blood vessel leakage and distortion, worsening inflammation and disease.


Learn more: OHSU Knight Cancer Institute offers the latest treatments, technologies, hundreds of research studies and clinical trials


“When we removed perivascular cells, blood vessels essentially failed to respond to tissue changes,” Franca said.


The findings shed light on the relationship between the extracellular matrix, blood vessel function and disease progression. Perivascular cells could become targets for therapies aimed at restoring normal vascular function and reducing the progression of various diseases such as fibrosis, diabetes and cancer.


Importantly, the research also holds promise for cancer prevention and early intervention. Early detection and treatment of changes in these cells could help stop tumors before they grow.


“If we intervene early, we might prevent precancerous lesions from advancing to full-blown cancer,” Bertassoni said. “This could revolutionize how we approach cancer prevention and treatment.”


Reference: Franca CM, Lima Verde ME, Silva-Sousa AC, et al. Perivascular cells function as key mediators of mechanical and structural changes in vascular capillaries. Sci Adv. 2025;11(2):eadp3789. doi: 10.1126/sciadv.adp3789


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