Project Manus – MIT
“Our technique combines low cost materials with a high-rate manufacturing process that has the potential of meeting the need for face shields nationwide.”
To address the critical shortage of personal protective equipment (PPE) due to COVID-19 cases, MIT has launched a new technique to meet the high demand for disposable face shields.
The sheer volume of PPE needed to keep both doctors and their patients safe in this current crisis is daunting – for example, tens of millions of disposable face shields will be needed nationwide each month.
“These face shields have to be made rapidly and at low cost because they need to be disposable,” explains Martin Culpepper, professor of mechanical engineering, director of Project Manus, and a member of MIT’s governance team on manufacturing opportunities for COVID-19.
“Our technique combines low-cost materials with a high-rate manufacturing process that has the potential of meeting the need for face shields nationwide.”
The single-piece face shield design will be made using a process known as die-cutting. Machines will cut the design from thousands of flat sheets per hour. Once boxes of these flat sheets arrive at hospitals, healthcare professionals can quickly fold them into three-dimensional face shields before adjusting for proper face.
“These face shields have to be made rapidly and at low cost because they need to be disposable,” explains Martin Culpepper, professor of mechanical engineering, director of Project Manus and a member of MIT’s governance team on manufacturing opportunities for COVID-19. “Our technique combines low-cost materials with a high-rate manufacturing process that has the potential of meeting the need for face shields nationwide.”
Culpepper and his team at Project Manus spearheaded the development of the technique in collaboration with a number of partners from MIT, local-area hospitals, and industry. The team has been working closely with the MIT Medical Outreach and the Crisis Management Unit established by Vice President for Research Maria Zuber and directed by Professor Elazer R. Edelman.
Initial fabrication of the shields will be done by Polymershapes based in Boston, Massachusetts with plans to expand across the country through fifty-five additional Polymershapes locations.
Extending the life of face masks
When used correctly, face masks should be changed every time a doctor or nurse treats a new patient. However, over the past month, many healthcare professionals have been asked to wear one face mask per day. That one mask could carry virus particles on them – potentially contributing to the spread of COVID-19 within hospitals and endangering healthcare professionals.
“The lack of adequate protective equipment or the idea of reusing potentially contaminated equipment is especially frightening to healthcare workers who are putting their lives, and by extension the lives and well-being of their families, on the line every day,” explains Edelman, Director of MIT’s Institute for Medical Engineering and Science, Edward J. Poitras Professor in Medical Engineering and Science, and leader of MIT’s PPE task force that Culpepper serves on.
Face shields can address this problem by providing another device for protection covering the entire face, adding a layer of protection the covers masks and more while extending the life of face masks and respirators. The shields are made of clear materials and have a shape similar to a welder mask. They protect the healthcare professional and their face mask from coming in direct contact with virus particles spread through coughing or sneezing.
“If we can slow down the rate at which healthcare professionals use face masks with a disposable face shield, we can make a real difference in protecting their health and safety,” explains Culpepper.
Culpepper and his team at Project Manus set out to design a face shield that could be rapidly produced at a scale large enough to meet the growing demand. They landed on a flat design that people could quickly fold into a three-dimensional structure when the shield was ready for use. Their design also includes extra protection with flaps that fold under the neck and over the forehead.
As much of MIT’s campus came to a halt in light of social distancing measures being put in place, Culpepper started prototyping using a laser cutter he had in his house. Along with some design input from his children, he tested different materials and made the first ten prototypes at home.
“When you’re thinking of materials, you have to keep supply chains in mind. You can’t choose a material that could evaporate from the supply chain. That is a challenging problem in this crisis,” explains Culpepper. After testing a few materials that cracked and broke when bent, the team chose polycarbonate and polyethylene terephthalate glycol – known more commonly as PETG – as the shield’s material.
In addition to making more prototypes at the Project Manus Metropolis Makerspace using a laser cutter, Culpepper worked with Professor Neil Gershenfeld and his team at MIT’s Center for Bits and Atoms (CBA) on rapid-prototyping designs for testing using a Zund large-format cutter.
Gershenfeld’s team at CBA is working on a number of projects for coronavirus response using its digital fabrication facility at MIT as well as the global Fab Lab network it launched. “The coronavirus response site is a great resource for those that are interested in working on solutions for PPE and devices for the COVID-19 pandemic,” Culpepper adds.
“It’s been a pleasure in this difficult time collaborating with such an impressive group, drawing on all of the Institute’s strengths to quickly define and refine a solution to an urgent need,” says Gershenfeld. “The work at MIT will be valuable beyond its immediate local impact, as a best-practices reference for the many other face shield projects emerging around the world.”
Testing the shield at local hospitals
With a number of working prototypes built, Culpepper and his team moved to the testing phase after consultation with, and practical feedback from, Edelman, who is a physician himself.
“The single greatest insecurity of a healthcare provider is the thought that we will become infected and in doing so be unable to perform our duties or infect others,” adds Edelman.
Edelman demonstrated how to store, assemble, and use the face shields to nurses and physicians at a number of local-area hospitals. Participants were then asked to use them in real-life situations and provide feedback using a one-page survey.
The feedback was overwhelmingly positive – participants found that in addition to being easy to assemble and use, the MIT-designed shields provided good protection against coming in contact with virus particles through splashes or aerosolized particles.
Armed with this feedback, Culpepper’s team made a few minor adjustments to the design to maximize coverage around the sides and neck of users. With the design finalized, the project has this week shifted to high-rate mass manufacturing.
High-rate mass manufacturing
Starting this week, fabrication company Polymershapes will start the mass production of the face shields. The die cutting machines used in mass manufacturing will produce the flat face shields at a rate of 50,000 shields per day in a few weeks. The manufacturer will continue to ramp up and increase the rate of manufacturing further with the ability to fabricate in more than eighty facilities nationwide.
“This process has been designed in such a way that there is the potential to ramp up to millions of face shields produced per day,” explains Culpepper. “This could very quickly become a nationwide solution for face shield shortages.”
MIT plans on purchasing the first 40,000 face shields to donate to local Boston-area hospitals this week and Polymershapes will donate 60,000.