U of T Engineering professor Kamran Behdinan (MIE) and a team of researchers at the University Health Network (UHN) are designing a life-saving device they hope never has to be used.
The team’s prototype of a low-cost breathing machine — known as a high acuity, limited operability (HALO) ventilator system — is now undergoing clinical testing and could be deployed if Toronto hospitals run out of ventilators for COVID-19 patients.
The device automates the squeezing motion needed to operate a ventilator bag, which is normally done by hand.
“This device should be used as a last resort,” says Behdinan. “But we wanted to make sure that hospitals have something to fall back on, if they are overwhelmed with patients in critical need of ventilation.”
Patients with severe cases of COVID-19 experience respiratory impairment that requires ventilation support. However, general-purpose ventilators are in limited supply in Canada and around the world, as manufacturing shortfalls are common due to their complicated design. A 2015 study estimates that there are about 15 ventilators per 100,000 people in Canada.
“In the time of a pandemic, ventilator shortages become a critical problem,” says Behdinan, who collaborated with Toronto-based Mackenzie Health and machine-shop staff at the Department of Mechanical & Industrial Engineering (MIE) to design a preliminary proof of concept in mid-March.
The initial prototype was based on a double-fulcrum design, where two “arms” pivot around a hinge on each end. To press down on the ventilator bag, the ends of the arms are brought together by a pulley located at the centre of the supporting base. A sensor then sends feedback to an Arduino microcontroller that adjusts the pressure on the ventilator.
Preliminary tests performed in the MIE Machine Shop showed that the device could produce up to 25 breaths per minute and provide a volume of approximately 450 mililetres, meeting key respiratory parameters.
Behdinan has since connected with a team of physicians at the Toronto General Hospital to assess, prototype, test and refine the HALO design to allow for more rapid manufacturing and deployment. The result is an advanced and streamlined HALO prototype that is now headed for clinical trials.
“Once we get through these trials, then the goal is to manufacture enough to quickly deploy to hospitals,” says Behdinan. “Hopefully they save lives. But hopefully they don’t have to.”
– This story was originally published on the University of Toronto’s Faculty of Applied Science and Engineering News Site on April 27, 2020 by Liz Do