Small droplets can easily move round the sides of the visor, the study found.
A new visualization shows why face shields and masks with exhalation valves might not be the simplest barriers for preventing the spread of COVID-19.
Although face shields initially block droplets from a simulated cough, small droplets can easily move round the sides of the visor and eventually cover an outsized area, consistent with the visualization, which is detailed during a study published Tuesday (Sept. 1) within the journal Physics of Fluids.
For masks with exhalation valves, a stream of droplets passes, unfiltered, through the valve, meaning the mask would in theory do little to hinder the spread of potentially infectious droplets.
In contrast, the researchers previously showed that some cotton face masks reduce the spread of droplets to only a couple of inches from the face during a simulated cough.
The simulations within the new study "indicate that face shields and masks with exhale valves may not be as effective as regular face masks in restricting the spread of aerosolized droplets," the authors wrote.
Face masks became a part of lifestyle during the COVID-19 pandemic. But some people are turning to plastic face shields or masks with exhalation values because they find these alternatives easier to wear for long periods of your time . Face shields even have the advantage of allowing users to point out facial expressions.
However, the Centers for Disease Control and Prevention (CDC) doesn't recommend either of those as alternatives to cloth masks. Masks with one-way valves, which are intended to be used in construction work, allow users to inhale filtered air and exhale warm, moist (and unfiltered) air through the valve. But because respiratory droplets from the wearer are expelled into the air, the CDC says people shouldn't wear these masks to stop COVID-19 spread.
The CDC also doesn't recommend face shields as a substitute for cloth masks because evidence is lacking to point out their effectiveness, the agency says.
"As students return to schools and universities, some have wondered if it is better to use face shields, as they are more comfortable and easier to wear for longer periods of time," study lead author Siddhartha Verma, an professor at Florida Atlantic University's College of Engineering and computing , said during a statement. "But what if these shields are not as effective? you would be essentially putting everyone in a tight space with droplets accumulating over time, which could potentially lead to infections."
In the new study, the researchers simulated coughing by connecting a mannequin's head to a fog machine — which creates a vapor from water and glycerin — and using a pump to expel the vapor through the mannequin's mouth. They then visualized the vapor droplets using a "laser sheet" created by passing a green laser pointer through a cylindrical rod. during this setup, simulated cough droplets appear as a glowing green vapor flowing from the mannequin's mouth.
For the face shield simulation, the shield initially deflected droplets toward the bottom after a cough. But small droplets remained suspended at rock bottom of the shield then floated round the sides, eventually spreading about 3 feet (0.9 meters) to the front and sides of the mannequin. In some cases, the droplets spread backward, behind the mannequin, rather than forward.
For the mask with a valve, a jet of droplets skilled the valve within the front of the masks during coughing. Initially, this jet of droplets traveled toward the bottom , but eventually the droplets dispersed over a good area.
The researchers also tested two different brands of commercially available surgical masks. Both of those masks weren't recommended for medical use by the manufacturers. Although the masks looked similar, one brand was effective at stopping the forward spread of aerosolized droplets, while the opposite allowed a high number of droplets to leak through the mask.
"This indicates that even among commercially available masks which may appear to be similar superficially, there can be significant underlying differences in the quality and type of materials used for manufacturing the masks," the authors said.
Since the study was a simulation, it doesn't provide data on the exact conditions that might end in the spread of an infection. for instance , with SARS-CoV-2, the virus that causes COVID-19, it's unclear exactly how long the virus remains infectious within the air, and the way far infectious particles can travel, or what proportion virus is required to make an individual sick.
The authors also noted that "even the very best masks have some degree of leakage," Verma said. So "it's still important to maintain physical distance while wearing [masks] to mitigate transmission."
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