Researchers at the University of Nebraska Medical Center (UNMC) have received a five-year, $3.5 million grant funded by the National Institutes of Health to find out why stents don’t work well for treating peripheral artery disease (PAD).
PAD reduces or completely cuts off blood flow in the leg arteries. This results in pain, numbness of the feet, inability to walk, wounds that won’t heal, and amputation of the toes, feet, or legs. The risk factors include diabetes, smoking, high blood pressure, high cholesterol, obesity, and aging.
In the last decade, there’s been an explosion in treating PAD using angioplasty and stenting-a minimally invasive procedure in which the patient is awake and usually leaves the hospital the next day.
Stents, small tubular metal devices that doctors put in diseased arteries to keep them open, work well in the heart, but often fail in the leg arteries. Though PAD stents work for many patients, there is significant room for improvement as many patients require repeat procedures in as little as one or two years, said Jason MacTaggart, MD.
MacTaggart, a vascular surgeon, and Alexey Kamenskiy, PhD, a biomedical engineer, both assistant professors in the UNMC Department of Surgery, are co-principal investigators of the research study.
“There are several ways to treat PAD, but none of them are really very good,” MacTaggart said. “It’s frustrating for doctors and patients. Everybody is trying to build a better mouse trap, but nobody really has. With the support of the UNMC Department of Surgery and our team of collaborators, we are taking a rational approach to figure out why stents don’t work very well in the legs.”
Researchers will study donor cadavers and arteries of various ages and stages of disease to gain accurate information to design computer models that would be used to determine which stent is best to use in individual patients. The computer predictions will be verified in PAD patients receiving stents at Nebraska Medicine, UNMC’s hospital partner, and the VA Medical Center.
“Our goal is to help make better stents and to personalize PAD interventions. We analyze how these stents go into the artery, how they interact with the arterial wall as we walk, and how to make this interaction more favorable,” Kamenskiy said. “Right now there’s a lot of art to using stents in PAD. We are trying to do less art and more science.”
This article was adapted from information provided by UNMC.
