At this point in the pandemic, the level of protection offered by masks is so uncertain (10% 1%? 0.1%?) and likely to be so small that masks are little more than a Hail Mary for those that don’t have access to vaccines, respirators, or PAPRs. While a Hail Mary doesn’t technically mean that it “doesn’t work,” it’s pretty close, and making a big deal about these distinctions is becoming a little pedantic.
For the vaccinated, recommending masks (which may or may not offer a tiny extra bit of protection) over vastly more effective respirators due to a small-to-none hassle factor seems a bit silly. It’s much more reasonable to recommend respirators or nothing.
You said something about “pure speculation” earlier, but I think that’s what you’re engaging in here.
What makes you think that masks offer “10%? 1%? 0.1%?” protection? Indeed, what do you mean by those numbers? What actual model of transmission leads you to think this?
[EDITED to add:] Actually, maybe I misunderstood you; is the “10%? 1%? 0.1%?” meant to be an amount of protection (in which case, why also say “and likely to be so small that …”—aren’t you saying the same thing twice?) or a probability of any protection at all (in which case, what are you smoking?)? Again, what actual model of transmission is this based on?
What masks do is to reduce the fraction (viruses breathed in) / (viruses breathed out), by blocking the passage of droplets or changing the pattern of air flow. Unless the later strains have evolved teleportation or something, it seems unlikely that the factor by which this fraction has reduced in any given situation is much different now from before. I’ve had trouble finding really convincing figures, but it seems like the typical factor for a surgical mask is somewhere on the order of a 3x-10x reduction in the “outward” direction, larger when speaking or coughing than when just breathing normally (which is good, because speaking and coughing make you emit a lot more viruses if infected). “Inward” protection seems to be somewhat less—maybe 2x? Home-made cloth masks appear to be substantially inferior to (ordinary, cheap) surgical masks.
This would mean e.g. that the amount of time you need to spend near an infected person in order to get infected yourself is 3-10x greater if they’re masked, 6-20x greater if you both are.
If you think that somehow none of this works any more because of the newer more infectious strains, or that it’s all nonsense and actually masks never had any substantial effect at all, then you should either give credible evidence that it doesn’t or explain a plausible way in which it would have stopped working (or would never have worked). “There was a wave of infections and masks didn’t stop it” is not credible evidence; that just means that the virus was infectious enough that whatever masks did wasn’t enough, which is perfectly consistent with masks doing a lot.
We know that masks have poor performance, because while masks seem to have eliminated the flu and to have stopped or significantly slowed down the spread of the original variants, especially in Asia, masks failed to have the same effect on the newer variants which caused the fall/winter wave. And since Delta is even more contagious than those variants, masks will be even less effective than they were during the last wave. How you can claim that this is not evidence is beyond me.
I also doubt that it’s useful or even possible to accurately calculate the efficacy of masks for the latest variants without doing lab work. How would you quantify the decrease in efficacy caused by increased infectivity due to better binding of the variants to human cells? How much more virus particles do these variants produce, if any, and how does that relate to mask efficacy? Is mask efficacy a spectrum or are there thresholds that suddenly render masks 0% effective in most or many situations? But since we already know that masks offer poor performance anyway, quantify exactly how poor the performance is (10%, 1%, 0.1%, or whatever) doesn’t seem to be all that important.
Masks have become a dangerous distraction from far more effective interventions.
You still seem to be assuming that “poor performance” = “not on their own sufficient to stop the latest variants growing exponentially”, and that is just unambiguously wrong.
Do you, or do you not, have any information that isn’t broadly consistent with the following crude model? 1. An infected person emits virus particles at some (somewhat random) rate, more when speaking or coughing than when breathing normally. 2. If you breathe in virus particles, there is some probability that you get infected; the probability is higher when the number of virus particles is higher. 3. If the infected person is wearing a mask, then the rate at which they emit virus particles is reduced by a constant factor somewhere in the vicinity of 5x. 4. If the not-yet-infected person is wearing a mask, then the number of virus particles reaching them is reduced by a constant factor somewhere in the vicinity of 2x. 5. Newer variants are more infectious, meaning some combination of (a) infected people emit more virus particles, or (b) the probability of infection for a given intake of virus particles is higher.
If this model is somewhere near the truth, then the only way for masks to be near-useless (“10%, 1%, 0.1%”, as you put it—but I asked you to explain what these numbers are supposed to mean and you didn’t, and I would still like you to) is if the newer variants cause such a colossal increase in the number of virus particles put out by an infected person, or in how effectively infectious they are, that being near them even briefly basically guarantees getting infected. Because otherwise, if you and they both wear masks then that means something like a 10x increase in how much exposure you can have before getting infected, and if the unmasked figure would be (say) 2 minutes’ conversation at a 2m distance, then that would turn into 20 minutes, and I at least have plenty of conversations that are longer than 2 minutes but shorter than 20 minutes.
Do you have good reason to believe that that model is far from the truth?
If not, do you have good reason to believe that the new variants are basically infinitely infectious?
If not, is there some other reason why the argument above fails?
Or have you just determined to keep saying “masks are useless” over and over, without ever making your claims precise enough to be evaluated, and without any actual model of how infection happens by which to justify your claim?
Once again, I appreciate that you are arguing for using something more effective than masks. I agree that things more effective than masks are more effective than masks. But it seems to me that you are either making almost certainly false claims about the effectiveness of masks (if you are saying that they aren’t what-I-call-effective, that they don’t substantially extend the range of what one can do without substantial risk of infection) or else using very misleading language to make the claims you are (if you are only saying that they are not sufficient on their own to stop a wave of Delta-variant COVID-19 -- which I agree is almost certainly the case), and I wish you wouldn’t do either of those things.
Given the fact that we already know that masks have poor performance based on the what I’ve already mentioned, models are pointless for most situations.
If you’re referring to modelling a strategy of maximizing personal (rather than public) protection with a poor performing tool, models could help you do that, but in the case of masks, it will turn out that most strategies are impractical because 1) there will be too many variables to keep track of, 2) some variables will be impossible or hard to obtain, and 3) some variables will be hard to control even with perfect knowledge. With or without a mask, if the distance between people is far enough, infection will be avoided regardless of infectivity due to dilution. If the distance is between two people, you may be able to calculate a minimum safe distance if you know all of the variables. Some of these variables are room size, ventilation, infectivity, mask type, rates of breathing and vocalization, and vaccination status. You’d also need to know if the room was previously occupied and by whom. Some of these these variables will be known but some will not be. You’ll also need to recompute these variables once they change. If you’re dealing with a simple model with two people in which nothing changes, this strategy might work. But real world cases are almost nothing like this. What if you go to another room or another person walks in? Is the ventilation the same? Is the person vaccinated? What kind of mask are they wearing? How many people were in the room before you walked in (aerosols can become suspended for hours even if the people that generated them are no longer around)? Modeling this stuff quickly becomes impractical, and if you can avoid that by wearing a respirator, why bother?
“10%, 1%, 0.1%” was meant to poke fun at the attempt of precisely quantifying the poor performance of masks and is not based on any data.
At this point in the pandemic, the level of protection offered by masks is so uncertain (10% 1%? 0.1%?) and likely to be so small that masks are little more than a Hail Mary for those that don’t have access to vaccines, respirators, or PAPRs. While a Hail Mary doesn’t technically mean that it “doesn’t work,” it’s pretty close, and making a big deal about these distinctions is becoming a little pedantic.
For the vaccinated, recommending masks (which may or may not offer a tiny extra bit of protection) over vastly more effective respirators due to a small-to-none hassle factor seems a bit silly. It’s much more reasonable to recommend respirators or nothing.
You said something about “pure speculation” earlier, but I think that’s what you’re engaging in here.
What makes you think that masks offer “10%? 1%? 0.1%?” protection? Indeed, what do you mean by those numbers? What actual model of transmission leads you to think this?
[EDITED to add:] Actually, maybe I misunderstood you; is the “10%? 1%? 0.1%?” meant to be an amount of protection (in which case, why also say “and likely to be so small that …”—aren’t you saying the same thing twice?) or a probability of any protection at all (in which case, what are you smoking?)? Again, what actual model of transmission is this based on?
What masks do is to reduce the fraction (viruses breathed in) / (viruses breathed out), by blocking the passage of droplets or changing the pattern of air flow. Unless the later strains have evolved teleportation or something, it seems unlikely that the factor by which this fraction has reduced in any given situation is much different now from before. I’ve had trouble finding really convincing figures, but it seems like the typical factor for a surgical mask is somewhere on the order of a 3x-10x reduction in the “outward” direction, larger when speaking or coughing than when just breathing normally (which is good, because speaking and coughing make you emit a lot more viruses if infected). “Inward” protection seems to be somewhat less—maybe 2x? Home-made cloth masks appear to be substantially inferior to (ordinary, cheap) surgical masks.
This would mean e.g. that the amount of time you need to spend near an infected person in order to get infected yourself is 3-10x greater if they’re masked, 6-20x greater if you both are.
If you think that somehow none of this works any more because of the newer more infectious strains, or that it’s all nonsense and actually masks never had any substantial effect at all, then you should either give credible evidence that it doesn’t or explain a plausible way in which it would have stopped working (or would never have worked). “There was a wave of infections and masks didn’t stop it” is not credible evidence; that just means that the virus was infectious enough that whatever masks did wasn’t enough, which is perfectly consistent with masks doing a lot.
We know that masks have poor performance, because while masks seem to have eliminated the flu and to have stopped or significantly slowed down the spread of the original variants, especially in Asia, masks failed to have the same effect on the newer variants which caused the fall/winter wave. And since Delta is even more contagious than those variants, masks will be even less effective than they were during the last wave. How you can claim that this is not evidence is beyond me.
I also doubt that it’s useful or even possible to accurately calculate the efficacy of masks for the latest variants without doing lab work. How would you quantify the decrease in efficacy caused by increased infectivity due to better binding of the variants to human cells? How much more virus particles do these variants produce, if any, and how does that relate to mask efficacy? Is mask efficacy a spectrum or are there thresholds that suddenly render masks 0% effective in most or many situations? But since we already know that masks offer poor performance anyway, quantify exactly how poor the performance is (10%, 1%, 0.1%, or whatever) doesn’t seem to be all that important.
Masks have become a dangerous distraction from far more effective interventions.
You still seem to be assuming that “poor performance” = “not on their own sufficient to stop the latest variants growing exponentially”, and that is just unambiguously wrong.
Do you, or do you not, have any information that isn’t broadly consistent with the following crude model? 1. An infected person emits virus particles at some (somewhat random) rate, more when speaking or coughing than when breathing normally. 2. If you breathe in virus particles, there is some probability that you get infected; the probability is higher when the number of virus particles is higher. 3. If the infected person is wearing a mask, then the rate at which they emit virus particles is reduced by a constant factor somewhere in the vicinity of 5x. 4. If the not-yet-infected person is wearing a mask, then the number of virus particles reaching them is reduced by a constant factor somewhere in the vicinity of 2x. 5. Newer variants are more infectious, meaning some combination of (a) infected people emit more virus particles, or (b) the probability of infection for a given intake of virus particles is higher.
If this model is somewhere near the truth, then the only way for masks to be near-useless (“10%, 1%, 0.1%”, as you put it—but I asked you to explain what these numbers are supposed to mean and you didn’t, and I would still like you to) is if the newer variants cause such a colossal increase in the number of virus particles put out by an infected person, or in how effectively infectious they are, that being near them even briefly basically guarantees getting infected. Because otherwise, if you and they both wear masks then that means something like a 10x increase in how much exposure you can have before getting infected, and if the unmasked figure would be (say) 2 minutes’ conversation at a 2m distance, then that would turn into 20 minutes, and I at least have plenty of conversations that are longer than 2 minutes but shorter than 20 minutes.
Do you have good reason to believe that that model is far from the truth?
If not, do you have good reason to believe that the new variants are basically infinitely infectious?
If not, is there some other reason why the argument above fails?
Or have you just determined to keep saying “masks are useless” over and over, without ever making your claims precise enough to be evaluated, and without any actual model of how infection happens by which to justify your claim?
Once again, I appreciate that you are arguing for using something more effective than masks. I agree that things more effective than masks are more effective than masks. But it seems to me that you are either making almost certainly false claims about the effectiveness of masks (if you are saying that they aren’t what-I-call-effective, that they don’t substantially extend the range of what one can do without substantial risk of infection) or else using very misleading language to make the claims you are (if you are only saying that they are not sufficient on their own to stop a wave of Delta-variant COVID-19 -- which I agree is almost certainly the case), and I wish you wouldn’t do either of those things.
Given the fact that we already know that masks have poor performance based on the what I’ve already mentioned, models are pointless for most situations.
If you’re referring to modelling a strategy of maximizing personal (rather than public) protection with a poor performing tool, models could help you do that, but in the case of masks, it will turn out that most strategies are impractical because 1) there will be too many variables to keep track of, 2) some variables will be impossible or hard to obtain, and 3) some variables will be hard to control even with perfect knowledge. With or without a mask, if the distance between people is far enough, infection will be avoided regardless of infectivity due to dilution. If the distance is between two people, you may be able to calculate a minimum safe distance if you know all of the variables. Some of these variables are room size, ventilation, infectivity, mask type, rates of breathing and vocalization, and vaccination status. You’d also need to know if the room was previously occupied and by whom. Some of these these variables will be known but some will not be. You’ll also need to recompute these variables once they change. If you’re dealing with a simple model with two people in which nothing changes, this strategy might work. But real world cases are almost nothing like this. What if you go to another room or another person walks in? Is the ventilation the same? Is the person vaccinated? What kind of mask are they wearing? How many people were in the room before you walked in (aerosols can become suspended for hours even if the people that generated them are no longer around)? Modeling this stuff quickly becomes impractical, and if you can avoid that by wearing a respirator, why bother?
“10%, 1%, 0.1%” was meant to poke fun at the attempt of precisely quantifying the poor performance of masks and is not based on any data.
I don’t think further discussion in this thread is likely to prove fruitful.