Alliance Laundry Systems, a manufacturer of commercial laundry equipment, has helped to develop a protocol for the viral decontamination of certain models of N95 masks. The protocol potentially will quadruple the useful life of this important personal protective equipment (PPE), according to a news release. Research suggests masks could be decontaminated up to three times, while preserving fit and filtration.
This method of decontamination builds off evidence provided by the National Institutes of Health (NIH), which showed that submitting N95 masks to dry heating cycles (70C/158F),reduces the SARS-COV-2 viral load by three orders of magnitude.
“With the life-and-death importance of this protective equipment and its current scarcity, our company jumped at the chance to work collaboratively with graduate researchers on an N95 Decontamination task force at Stanford University to design a method that enables reuse of N95 masks,” said Rick Pyle, President and Chief Commercial Officer of Alliance Laundry Systems. “Alliance Laundry Systems engineers and research lab staff worked tirelessly to help craft this repeatable decontamination protocol and supply test data supporting it. We could not be prouder to help research a way to protect the brave men and women in healthcare and first-responder roles, who are on the front lines of this COVID-19 fight every day.”
Alliance Laundry Systems leveraged its state-of-the-art research and development lab to perform hundreds of hours of tests utilizing UniMac tumble dryers. The overarching goal was to develop a repeatable decontamination process that would help safely reuse certain models of N95 masks. Testing suggests that specific masks can be decontaminated up to three times without excessive damage to their fit and filtration. The CDC/NPPTL (NIOSH) labs provided filtration and fit data on new masks which underwent the decontamination treatment. Lab results and test data have now been submitted to the FDA for emergency use authorization (EUA).
The UniMac dryer’s unique heater box design and radial airflow pattern help, with proper programing and process validation, maintain the optimal decontamination temperature, while preserving the integrity of the specific N95 masks tested. Through a Stanford N95 Decontamination task force in the lab of Professor Manu Prakash, graduate student members, Edward Mazenc, Daniel Ranard, and Yuri Lensky, worked to study the viability of the temperature data findings for decontamination. Those findings are detailed in a final paper currently in peer review.
“These results indicate a significant leap forward in the reuse of N95 masks, and the availability of UniMac equipment not only in the United States, but also globally, brings unprecedented access to this repeatable process,” Pyle said.