Stiffening arteries could change cell behavior

February 26, 2009 By Lauren Gold
Stiffening arteries could change cell behavior
Endothelial cells. (Jospeh Califano)

( -- Like skin that loses elasticity, blood vessels lose their pliability and stiffen with age. In more than half of the U.S. population over 65, this stiffening of the blood vessels is accompanied by a buildup of plaque inside arterial walls -- atherosclerosis -- which can lead to blood vessel obstruction, increased stress on the heart and the risk of a heart attack.

Researchers have long known that factors like smoking and high cholesterol intake contribute to the disease. But Cynthia Reinhart-King, assistant professor of biomedical engineering at Cornell, is investigating atherosclerosis from a different perspective -- with hopes of finding new ways to treat it.

"Many scientists are very interested in the chemical factors that cause these plaque formations," she said. "What we're interested in is how the vessel stiffness changes the cells in the blood vessel and perhaps contributes to atherosclerosis."

To study the relationship, Reinhart-King, who is supported in part by an American Heart Association (AHA) Young Investigators grant, is observing how endothelial cells (which make up the inner lining of arteries) behave when attached to hard and soft surfaces. Specifically, she studies whether simply being attached to a stiffening artery -- instead of a young, supple one -- makes endothelial cells more susceptible to the buildup of plaque.

Her preliminary findings indicate that being attached to a stiffer blood vessel appears to reduce how tightly the cells that line the vessels attach to each other, which could make it easier for plaque deposits to form.

In a system adapted in her lab that mimics conditions inside a blood vessel (without the dozens of confounding variables that exist in the body) Renihart-King grows endothelial cells on polymer surfaces that match the elasticities of a healthy or diseased artery wall. Using a technique called traction force microscopy, which measures the cells' response to the substrate, she then looks for differences in the way the cells adhere to the polymer, how they arrange themselves in response to blood flow, and how tightly they bind to each other.

Changes in the strength of cell-to-cell binding -- or the permeability of the cell layer -- are key, Reinhart-King said.

"Normally, endothelial cells form very tight connections and not much can get through them," she said. But in atherosclerosis, those connections break down and cholesterol deposits form under the endothelial layer.

If her lab finds a definitive link between the mechanics of the substrate and the permeability of the cell layer, researchers could use that knowledge to develop new therapies that target that response -- instead of (or along with) therapies that seek to prevent vessel stiffening.

The research is perfectly suited to her role as a biomedical engineer, she said.

"As biomedical engineers, we like to combine novel tools with clinically relevant problems to come up with a solution. [In] this problem, we're looking at mechanical forces and cell behavior from a very biological point of view. So I think that we've found a niche where we can uniquely push the field forward."

The AHA's Young Investigators grant helps researchers at the beginning of their careers, she added. "We're all excited to have that grant," because it enables valuable research that can lead to bigger projects in the future, she said. "It's a really great catalyst."

Provided by Cornell University

Explore further: How cells 'climb' to build fruit fly tracheas

Related Stories

How cells 'climb' to build fruit fly tracheas

November 25, 2015

Fruit fly windpipes are much more like human blood vessels than the entryway to human lungs. To create that intricate network, fly embryonic cells must sprout "fingers" and crawl into place. Now researchers at The Johns Hopkins ...

Nanocarriers may carry new hope for brain cancer therapy

November 19, 2015

Glioblastoma multiforme, a cancer of the brain also known as "octopus tumors" because of the manner in which the cancer cells extend their tendrils into surrounding tissue, is virtually inoperable, resistant to therapies, ...

Recommended for you

How the finch changes its tune

August 3, 2015

Like top musicians, songbirds train from a young age to weed out errors and trim variability from their songs, ultimately becoming consistent and reliable performers. But as with human musicians, even the best are not machines. ...

Machine Translates Thoughts into Speech in Real Time

December 21, 2009

( -- By implanting an electrode into the brain of a person with locked-in syndrome, scientists have demonstrated how to wirelessly transmit neural signals to a speech synthesizer. The "thought-to-speech" process ...


Please sign in to add a comment. Registration is free, and takes less than a minute. Read more

Click here to reset your password.
Sign in to get notified via email when new comments are made.