Personalized Device Could Support Multiple COVID-19 Patients From Single Ventilator
3D printing fuels U-M efforts to rapidly increase ventilator capacity while providing each patient on vent support with individually tailored gas pressures and pressure monitoring.
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This story was updated on December 18, 2020.
As the pandemic swept across the nation in March, so did urgent questions about the virus’ potential strain on the healthcare system.
Among top concerns: whether the nation’s hospitals had enough ventilators to provide breathing support to critically ill patients with the disease COVID-19, which mainly attacks the lungs.
As experts predicted a surge in coronavirus cases and a possible shortage in intensive care unit equipment, University of Michigan teams immediately got to work on a solution. The mission: to quickly develop an efficient, affordable and more controlled way to expand ventilator capacity.
And within weeks, U-M and Michigan Medicine researchers had invented an individualized vent-splitter that could allow multiple patients to receive customized pressures while sharing a single ventilator. U-M filed for patent protection on the technology, and a local start-up, MakeMedical LLC, licensed the technology and developed it into the VentMI device.
The device was able to provide ventilation to two different animals at the same time with very different settings, according to findings in PLOS ONE, a scientific journal published by the Public Library of Science. One animal could also be operated on while ventilation was maintained on the other.
The VentMI device received emergency use authorization from the U.S. Food and Drug Administration in April, 2020. MakeMedical, which U-M inventors have equity in, will provide the device at cost to other institutions without any profit for U-M or the company.
“It has taken relentless positive action by a large number of individuals all motivated by the common good to make this happen,” says Glenn Green, M.D., a pediatric otolaryngologist at Michigan Medicine C.S. Mott Children’s Hospital and co-developer of the technology.
In spring, the team spent weeks using in-house 3D printing to rapidly develop multiple prototypes, test them on machines in a hospital operating room and evaluate how the technology worked on pigs. The FDA’s emergency authorization allows their device to be used on humans if needed.
The team has spent the last few weeks using in-house 3D printing to rapidly develop multiple prototypes, test them on machines in a hospital operating room and evaluate how the technology worked on pigs. The FDA’s emergency authorization now allows their device to be used on humans if needed.
“We have been working 24/7 to develop a system that could at least double ventilator capacity,” says otolaryngologist Kyle VanKoevering, M.D., of the department of otolaryngology-head and neck surgery at Michigan Medicine and an associate faculty member in the department of biomedical engineering at Michigan Engineering.
“We were looking for innovative ways to potentially help hospitals that were preparing for a ventilator shortage during the pandemic.”
The device is being manufactured in partnership with Grand Rapids facility Autocam Medical, with hundreds of devices available for public distribution before the end of April. MakeMedical, LLC will market the product domestically and internationally and is in the process of partnering with distributors.
MakeMedical cofounders include Green, VanKoevering, Mott pediatric head and neck surgeon David Zopf, M.D. and local business owner Owen Tien.
Quick collaboration to quickly solve a problem
SARS-CoV-2, a respiratory virus, can cause complications like pneumonia and respiratory distress. In severe cases, patients will require a ventilator, a device that is attached to the windpipe and supports a patient’s lungs while their body fights the infection.
Ventilators are also used for other types of conditions, including brain and spinal cord injuries that interfere with breathing and muscle, lung and sleep disorders.
Currently, there are significant limitations to more than one patient using the same ventilator at once. One of the biggest barriers is that, without individualized controls, shared ventilator circuits will deliver only one pre-set pressure to all patients sharing the same ventilator.
Patients sharing a ventilator need to have similarly-sized lungs with equal stiffness – or ability to stretch and expand.
“The problem is that for patients to share a ventilator using a currently available vent-splitter, they must have the same ventilator needs,” VanKoevering says. “Otherwise one person may receive excessive volume or pressure on their lungs, which can cause lung trauma.”
“Our design would have much broader use because it solves the problem of different ventilatory requirements and monitoring for people that have different lung sizes and degrees of disease.”
The system mimics a scuba tank regulator. A scuba tank contains compressed air at a very high pressure, but the regulator delivers it slowly at the pressure the lungs need to breathe.
“Every innovative idea that comes from our group starts from powerful inspiration; in this case, Dr. Vankoevering’s ideas on how to tailor lifesaving shared ventilation,” says Zopf, assistant professor of otolaryngology, head and neck surgery at Michigan Medicine and Mott and an affiliate professor in the department of biomedical engineering at Michigan Engineering.
“The idea propels forward from relentless effort and encouragement from the team.”
Researchers say because VentMI is inexpensive, light, mobile and readily deployable, it can be delivered quickly to any place that could use it. The individualized pressure regulator system for vent splitting is expected to cost up to a hundredth of the cost of a new ventilator.
“The speed with which our team developed, tested and verified this technology was incredible,” says Tien, co-developer of the technology and founder of Ann Arbor-based 3D printing company Thingsmiths.
“We couldn’t have done it without great industry partners and our access to, and knowledge of, 3D Printing, CAD design, and the best of rapid healthcare innovation.”
Tien especially credited Autocam's versatility and capacity to mobilize a precision-manufactured device in less than a week as being critical to the team’s success.
“They have been an enormous asset in this process," he says.
Researchers represent teams from Michigan Medicine otolaryngology, anesthesia and intensive care and University of Michigan biomedical engineering. While Michigan Medicine is among hospitals that currently have adequate ventilator capacity, researchers wanted to make the device available to any hospitals anticipating a shortage.
“We plan to make the devices available to be used across the world,” VanKoevering says. “Our goal is to help provide lifesaving care to every critically ill patient who needs it during this pandemic.”
Hospitals and centers that are interested in receiving the device, may make inquiries online.