Via Forbes: (https://www.forbes.com/sites/brucelee/2020/03/29/making-an-n95-mask-for-covid-19-coronavirus-what-you-need-to-know/)
By now, you’ve probably heard that there is shortage of N95 masks for health care professionals trying to deal with the COVID-19 coronavirus pandemic. The shortage has motivated a number of DIY (do-it-yourself) efforts by well-meaning folks to make masks that are not exactly official N95 masks. While the intents behind such efforts are admirable, it will be important to have the design and manufacturing of such masks follow the science of N95 respirators.
The stakes are high when designing an alternative mask. A shortage of N95 masks isn’t like a shortage of throw pillows. Lack of such protection for health care workers can make it much more likely for them to get infected with the severe acute respiratory syndrome coronavirus 2 (SARS-CoV2). This not only puts them at risk but also other patients seen by such health care workers. So an incorrect design will have a lot deeper consequences than just bad Amazon reviews.
It’s not clear whether this would be to replace simple masks and hospital gowns that don’t need to filter out small particles or to replace N95 respirators as well. If it’s the former then jersey material could work, again as long as it is for situations where filtering small particles like viruses is not needed. Plus, there’s the added advantage of you looking like either a New York Yankees player or a topographical map, whichever you happen to prefer. Additionally, such “jersey masks” could provide some benefits while placed on patients who are infected with the SARS-Cov2. This could catch their coughing and sneezing so that they are at least a little less likely to infect others.
However, masks using such material would not adequately protect doctors, nurses, and other health care professionals working directly with patients who may be infected with SARS-CoV2. Jersey material does not have the characteristics necessary to filter out very small virus particles. In fact, any DIY efforts should keep in mind the following eight qualities that a N95 mask or the equivalent should have:
The mask is called N95 and not “N let’s see what can and can’t get through the mask.” N95 means that the mask can filter out at least 95% of particles of all sizes from the air. That includes something less than 0.1 microns in size and something as large as a watermelon. Note, if watermelons are flying through the air, it helps to duck as well.
Basically, the mask needs keep the virus from reaching your nose and mouth, which is why wearing panty hose over your head like a gangster isn’t going to do the trick. “Something like panty hose is too porous,” explained Sundaresan Jayaraman, PhD, the Kolon Professor at the Georgia Institute of Technology School of Materials Science & Engineering. “That’s the case with many types of fabric. Even when you use several layers of fabric, it may have too many holes.” He added that one layer of a handkerchief or bandana is only going to filter out less than 10% of particles.
Polypropylene is a commonly used material for N95 masks. To get through a filter made out of interlaced layers of polypropylene fibers, small particles have to wind through a rather tortuous path and as a result tend to get stuck, as described by a National Academies of Science, Engineering, and Medicine (NASEM) report that Jayaraman helped author. Think about getting through the filter material as getting through the entire crowd at a BTS concert. However, creating a tortuous path isn’t the only way that polypropylene makes it difficult for viruses to pass.
If you are trying to keep someone from getting into the nightclub that you call your body, you would want multiple ways to keep him or her from entering. That way if one mechanism fails, the others are there. The NASEM report described three general mechanisms that N95 masks have to pull particles from the air stream: inertial impaction, diffusion, and electrostatic attraction. Inertial impaction sounds like a dance move or a dental procedure. But it is when the tortuous path makes it difficult for particles that are 1 μm and larger to continue on their straight paths. Such particles are too large to weave through the mask fibers and end up running into one the fibers.
The second mechanism, diffusion, helps keep particles that are 0.1 μm and smaller from proceeding. The design of the mask filter creates a situation in which these very small particles move in random directions, colliding with each other and with filter fibers. When these particles are bouncing against each other as if they were in a mosh pit, it less likely that they will get though the maze.
The third mechanism, electrostatic attraction, sounds like something someone would say on a Tinder conversation. The filter material for N95 doesn’t just physically block viruses and other small particles. As the song goes, you can’t see it, it’s electric. During the manufacturing process, the fibers receive an electric charge. As Jayaraman described, “this electrostatic charge then attracts the virus so that it gets stuck on the fibers.” This is one case where forced attraction is a good thing.
Lots of materials could keep the virus out like cement or Saran Wrap. There’s one slight problem with such materials though. You have to be able to breathe, which is why you have your nose in the first place. Breathing resistance is not a movement against breathing, but instead how difficult a mask makes it to breathe. “You have to make sure the breathing resistance is not too high for a mask,” said Jayaraman. “Wrapping your face with Saran wrap may keep viruses out but the breathing resistance would be too high. The same would be true for many layers of fabric.” Low enough breathing resistance is important both for the inhale as well as the exhale. if air can’t get back out through the mask, it could blow up like a balloon.
Wearing a mask that filters out the virus but does not form a tight seal with your face can be like locking the front doors of your car but not the back. Any gaps between the mask and your face can allow the virus to sneak into your nose or mouth. That’s why you should be fit-tested for a N95 mask before actually using it.
OK, the phrase “slip into something more comfortable” usually doesn’t mean put on a N95 mask. If a date ends with N95 masks on, something probably has gone wrong. There will always be some level of discomfort wearing such a mask. Nevertheless, the mask can’t be too uncomfortable. The edges of the mask can’t be so sharp or abrasive that they cause substantial irritation, sores, or cuts. The mask can’t be so tight that you feel like your head is going to explode.
The song “Pieces of Me” shouldn’t apply to your mask. Anything that breaks off or sheds from your mask such as fibers and little particles can go straight up your nose and potentially down into your lungs. And that’s not good.
Health care settings aren’t exactly rom-coms. Things rarely go perfectly. They can be quite chaotic with unexpected splashing of liquids. Plus, you breathe out water vapor from your mouth and also may spit while you talk. If you believe that you don’t spit at least occasionally when talking then you probably believe that you don’t fart either. The mask has to be reasonably resistant to all of these possibilities and maintain its integrity and filtering capabilities at least for a while.
This can be like making a highway too narrow. A too narrow passageway may not only increase breathing resistance but also lead water droplets to coalesce. Coleascing water droplets can make the filter wet and thus decrease its effectiveness.
All of this being said, N95 respirators are not the only option to protect health care workers from SARS-CoV2 in the air. For example, reusable elastomeric respirators may provide superior protection compared to N95 masks. A drawback is that they can make you “look like Darth Vader,” in the words of Jayaraman. But as long as you don’t say “feel the power of the Dark Side” or “I am your father,” this may not be such a bad thing. So while any new design of a respirator should have the qualities mentioned above, it doesn’t have be exactly the same as a N95 respirator. Who knows, one good thing that could come out of the COVID-19 coronavirus pandemic may be some new respirator designs.
Again, there are a lot of well-meaning people out there trying to address the N95 mask shortage. However, masks that are not designed to provide appropriate levels of filtering, porosity, and comfort are not replacements for N95 respirators. If health care workers mistakenly believe that DIY masks will provide the same level of protection that N95 respirators do, if the availability of such masks convinces hospitals and health care systems that they do not need to urgently pay for legitimate N95 respirators, or if such masks somehow prevent policy makers from taking more urgent action to rectify the shortage with real OSHA-compliant masks, then such DIY masks could end up doing more harm than good.
It’s heartwarming to see so many people trying to cover the shortage of N95 respirators. Protecting health care professionals should be paramount. Just make sure that the limitations of any DIY mask are clearly covered or rather uncovered for everyone to clearly see. And that the design of any masks trying to serve as replacements for N95 respirators clearly cover the scientific principles that need to be covered.