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Concordia researchers develop a new method to evaluate the health of artificial heart valves

The technique can help physicians detect blood flow blockages in recipients
June 19, 2019
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From left: Lyes Kadem and Ahmed Darwish. Cardiologists and their patients who have received mechanical heart valve replacements will benefit from Concordia-led research.
From left: Lyes Kadem and Ahmed Darwish. Cardiologists and their patients who have received mechanical heart valve replacements will benefit from Concordia-led research.

Researchers at Concordia have devised a technique to detect obstructions in a type of mechanical heart valve they believe will contribute to safer follow-up methods for cardiologists and their patients.

The team led by Lyes Kadem, professor in the Department of Mechanical, Industrial and Aerospace Engineering at the Gina Cody School of Engineering and Computer Science, published their findings in the journal Artificial Organs. PhD candidate Ahmed Darwish was lead author, and Giuseppe Di Labbio, assistant professor Wael Saleh and Othman Smadi of Hashemite University in Jordan contributed.

The researchers used high-tech equipment to look at the flow downstream of a bi-leaflet mechanical heart valve (BMHV). The equipment included a custom-made double-activation left heart duplicator designed and created in their lab by Concordia undergraduate students, a high-speed camera and a laser.

Despite the impressive name, the BMHV is a simple ring with an inner diameter of about 2.5 cm. Two carbon-based leaflets inside the ring open and close as the heart pumps blood out of the left ventricle and into the aortic arch, which sends the blood out into the body.

They replace damaged aortic valves, and are installed via open-heart surgery. An obstructed BMHV can be catastrophic.

Mapping blood flow

The method the team designed maps simulated blood flow patterns that result from six different heart valve blockages. The researchers photographed particles immersed in a liquid that mimics blood and pumped the fluid through the heart duplicator.

Using a technique called particle image velocimetry, they were able to determine the flow velocity. It allowed them to simulate what blood flow would look like with the leaflets completely clear of obstruction, when they were partially obstructed and when fully obstructed.

“Imagine you are outside a stadium and the crowd is leaving from three gates next to each other,” says Kadem, the Concordia Research Chair for Cardiovascular Engineering and Medical Devices.

“If the gates are open, you will see a uniform distribution of people leaving from all three openings. If one gate is closed, you will see more people leaving from the two others, and none from the one that is closed. Therefore, you will deduce that there is a blockage.”

When applied using phase-contrast magnetic resonance imaging (MRI), the method is both non-invasive and radiation-free, says Kadem. That means doctors can use it for BMHV dysfunction detection and follow-up.

“Currently, ultrasound is the best way to detect valve dysfunction,” he says. “The next step is cinefluoroscopy, which uses radiation. You can’t use this method as a follow-up because it exposes the patient to radiation and increases their risk of cancer.”

Darwish and Kadem note that artificial heart valves are generally safe but are not risk-free. There is between 0.1 per cent and 6 per cent chance of dysfunctions that can occur between one hour and 20 years after they replace the organic valve. These can be fatal, with a 28.6 per cent mortality rate when a dysfunction results in an emergency.

This research is supported by a grant from the Natural Sciences and Engineering Research Council of Canada.


Read the cited paper: Experimental investigation of the flow downstream of a dysfunctional bileaflet mechanical aortic valve.

 

Contact

Patrick Lejtenyi
Public Affairs
514-848-2424, ext. 5068
patrick.lejtenyi@concordia.ca
@ConcordiaUnews


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