I'm amazed that wasn't taken into account! Many years ago, in the final year of my Biology degree, I did a paid summer internship at an Evolutionary Biology lab here in Spain, assisting in a project where they were researching relationships between metal ion accumulation (mostly zinc) and certain SNPs (≈"gene varieties"). A lot of my work was in slicing tiny fragments of deep-frozen human livers and kidneys in a biosafety cabinet over dry ice.<p>The reason I bring this up is because the researchers had taken the essential precaution of providing me with a <i>ceramic</i> knife to do the cutting (and platic pliers), to eliminate the risk of contaminating the samples with metal from ordinary cutting implements.<p>That some research on microplatics did not take into account the absolutely mental amount of single-use plastic that is involved in biological research, particularly gloves of all things, boggles the mind.
>>That some research on microplatics did not take into account the absolutely mental amount of single-use plastic that is involved in biological research, particularly gloves of all things, boggles the mind<p>What boggles the mind is you commenting on an article you clearly did not read...stating something that is not there...
> I'm amazed that wasn't taken into account!<p>Agreed. While I didn’t anticipate this myself, nor would have likely figured it out myself, I also don’t expect my claims to influence global policy.<p>The scientists who failed to realize this <i>do</i> expect that, so the standards we expect from them need to be higher in accordance with that.
>> I'm amazed that wasn't taken into account!<p>This was taken into account: <a href="https://news.ycombinator.com/item?id=47563392">https://news.ycombinator.com/item?id=47563392</a>
You found a paper saying that contamination is possible. That doesn’t mean that most of these plastic studies are doing the necessary controls, let alone the (almost impossible) task of preventing the contamination in a laboratory setting where nanomolar detection levels are used to make broad claims.
Are more “controls” what is necessary here? The problem wasn’t plastic contamination, it was the presence of stearates. Distinguishing between stearates and microplastics sounds like a classification problem, not a control problem.<p>There is practically universal recognition among microplastics researchers that contamination is possible and that strong quality controls are needed, and to be transparent and reproducible, they have a habit of documenting their methodology. Many papers and discussions suggest avoiding all plastics as part of the methodology, e.g. “Do’s and don’ts of microplastic research: a comprehensive guide” <a href="https://www.oaepublish.com/articles/wecn.2023.61" rel="nofollow">https://www.oaepublish.com/articles/wecn.2023.61</a><p>Another thing to consider is that papers generally compare against baseline/control samples, and overestimating microplastics in baseline samples may lead to a lower ratio of reported microplastics in the test samples, not higher.
Many papers in this field are missing obvious controls, but you’re correct that controls alone are insufficient to solve this problem.<p>When you are taking measurements at the detection limit of <i>any</i> molecule that is widespread in the environment, you are going to have a difficult time of distinguishing signal from background. This requires sampling and replication and rigorous application of statistical inference.<p>> Another thing to consider is that papers generally compare against baseline/control samples,<p>Right, that’s what a control is.<p>> and overestimating microplastics in baseline samples may lead to a lower ratio of reported microplastics in the test samples, not higher.<p>There’s no such thing as “overestimating in baseline samples”, unless you’re just doing a different measurement entirely.<p>What you’re trying to say is that if there’s a chemical everywhere, the prevalence makes it harder to claim that small measurement differences in the “treatment” arm are significant. This is a feature, not a bug.
You’re still bringing up different issues than this article we are commenting on.<p>> There’s no such thing as “overestimating in baseline samples”<p>What do you mean? Contamination and mis-measurement of control samples is a thing that actually happens all the time, and invalidates experiments when discovered.<p>> What you’re trying to say is that if there’s a chemical everywhere, the prevalence makes it harder to claim that small measurement differences in the “treatment” arm are significant.<p>No. What I was trying to say is that if the control is either mis-measured, for example by accidentally counting stearates as microplastics, or contaminated, then the summary outcome may underestimate or understate the prevalence of microplastics in the test sample, even though the measurement over-estimated it.
Any scientific paper that does not document how things were done (methodologies) is basically worthless in the search for truth.
I agree completely. My point is that documenting methodology is standard practice, as is strict quality control, in the microplastics literature. I don’t know what controls are missing according to GP, and we don’t yet have references here to back up that claim. By and large I think researchers are aware of the difficulties measuring this stuff, and doing everything they can to ensure valid science.
>> That doesn’t mean that most of these plastic studies are doing the necessary controls<p>That was never my argument. Read it again.
Not OP, but:<p>> "You found a paper"<p>johnbarron didn't find it. The authors cited it as foundational to their own work. it's ref. 38 in the paper under discussion. From the paper: "this finding had not been reported in the MP literature until 2020, when Witzig et al. reported that laboratory gloves submerged in water leached residues that were misidentified as polyethylene."[1]<p>> "most of these plastic studies are [not] doing the necessary controls"<p>which studies? The paper they linked surveys 26 QA/QC review articles[1]. Seems well understood.<p>> "a laboratory setting where nanomolar detection levels are used to make broad claims"<p>This is like saying "miles per gallon" when discussing weight. "nanomolar detection levels"...microplastics are individual particles identified by spectroscopy, reported as particles per mm^2. "Nanomolar" is a dissolved-species concentration unit. It has nothing to do with particle counting. (I, and other laymen, understand what you mean but you go on later in the thread to justify your unsourced and unjustified claims here via your subject-matter expertise.)<p>> "(almost impossible) task of preventing the contamination"<p>The paper provides open-access spectral libraries and conformal prediction workflows to identify and subtract stearate false positives from existing datasets[1]. Prevention isn't the strategy. Correction is. That's the entire point of the paper they linked and the follow-up in [2]<p>[1] <a href="https://pubs.rsc.org/en/content/articlehtml/2026/ay/d5ay01801" rel="nofollow">https://pubs.rsc.org/en/content/articlehtml/2026/ay/d5ay0180...</a><p>[2] <a href="https://news.umich.edu/nitrile-and-latex-gloves-may-cause-overestimation-of-microplastics-u-m-study-reveals/" rel="nofollow">https://news.umich.edu/nitrile-and-latex-gloves-may-cause-ov...</a>
> This is like saying "miles per gallon" when discussing weight. "nanomolar detection levels"...microplastics are individual particles identified by spectroscopy, reported as particles per mm^2. "Nanomolar" is a dissolved-species concentration unit. It has nothing to do with particle counting. (I, and other laymen, understand what you mean but you go on later in the thread to justify your unsourced and unjustified claims here via your subject-matter expertise.)<p><i>This paper</i> used “light-based spectroscopy” [1]. Many others use methods that depend on gas chromatography or NMR. A relatively infamous recent example used pyrolysis GCMS to make low-concentration measurements (hence: nanomolar), which they credulously scaled up by some huge factor, and then made idiotic claims about plastic spoons in brains.<p>Relatively little quantitative science in this area depends on counting plastic particles in microscopic images, but it’s what gets headlines, because laypeople understand pictures.<p>[1] as an aside, the choice of terminology here is noteworthy. A simple visual light absorption spectra is also “light based spectroscopy”, but is measuring the aggregate response of a sample of a heterogeneous mixture, and is conventionally converted to molar equivalents via some sort of calibration curve (otherwise you can’t conclude anything). But there could be other approaches that are closer to <i>microscopy</i>, which they also discuss. “Particles per square millimeter” is <i>also</i> a unit of concentration (albeit a shitty one, unless your particles are of uniform mass).<p>Anyway, the point is that these kinds of quantitative analyses are all trying to do measurements that are fundamentally about <i>concentration</i>, which is why I chose the words that I did.
> ...<p>"1 nanomole of polyethylene" requires you to pick an arbitrary average molecular weight.<p>This changes the answer by orders of magnitude depending on what you pick.<p>Which is why nobody does it.<p>> Relatively little quantitative science in this area depends on counting plastic particles in microscopic images...Many others use methods that depend on gas chromatography or NMR.<p>So we're dismissive of some subset of papers, because they get false positives using toy methods.<p>Real science would use gas chromatography.<p>But...the paper we're dismissing tested gas chromatography. And found the same false positive. [1, in abstract]<p>> A relatively infamous recent example used pyrolysis GCMS to make low-concentration measurements (hence: nanomolar)<p>The brain study I'm guessing you are referring to, [2], measured low concentrations, yes.<p>But it reported them in ug/g.<p>Because polymers don't have a defined molecular weight.<p>> made idiotic claims about plastic spoons in brains<p>The brain study I'm guessing you are referring to, [2], does not mention spoons, or, come close.<p>Are we sure there's a paper that did that?<p>[1] Witzig et al, <a href="https://pubs.acs.org/doi/10.1021/acs.est.0c03742" rel="nofollow">https://pubs.acs.org/doi/10.1021/acs.est.0c03742</a>, "Therefore, u-Raman, u-FTIR, and pyr-GC/MS were further tested for their capability to distinguish among PE, sodium dodecyl sulfate, and stearates. It became clear that stearates and sodium dodecyl sulfates can cause substantial overestimation of PE."<p>[2] Campen et al, <a href="https://pubmed.ncbi.nlm.nih.gov/38765967/" rel="nofollow">https://pubmed.ncbi.nlm.nih.gov/38765967/</a>, "Bioaccumulation of Microplastics in Decedent Human Brains"
Luckily HN software developers, the foremost authority on literally every subject imaginable, are here to bless the world with their insights.
I think there's an important distinction of smug better-knowing instances.<p>"I have unique insight as a non-expert that all experts miss and the entire field is blind to" -> usually nonsense<p>"I think in this specific instance academically qualified people are missing something that's obvious to me" -> often true.
Spiritual equivalent of a life sciences forum discovering memory safety, one person who wrote code for a bit saying they wrote a memory bug in C once, then someone clutching pearls about why all programmers irresponsibly write memory unsafe code given it has a global impact.<p>Been here 16 years, it's always an adventure seeing whether stuff like this falls into:<p>A) Polite interest that doesn't turn into self-keyword-association<p>B) Science journalism bad<p>C) Can you believe no one else knows what they're doing.<p>(A) almost never happens, has to avoid being top 10 on front page and/or be early morning/late night for North America and Europe. (i.e. most of the audience)<p>(B) is reserved for physics and math.<p>(C) is default leftover.<p>Weekends are horrible because you'll get a "harshin' the vibe" penalty if you push back at all. People will pick at your link but not the main one and treat you like you're argumentative. (i.e. 'you're taking things too seriously' but a thoughtful person's version)
<i>> Spiritual equivalent of a life sciences forum discovering memory safety, one person who wrote code for a bit saying they wrote a memory bug in C once, then someone clutching pearls about why programmers irresponsibly write memory unsafe code given it has a global impact.</i><p>I used to be a code monkey, I wrote systems software at megacorps, and still can't understand why so many programmers <i>irresponsibly write memory unsafe code given it has a global impact</i>.<p>So Poe's law applies here.
That's the analogy working as intended: the answer to "why do programmers still write memory-unsafe code" is the same shape as "why do microplastics researchers still wear gloves." The real answer is boring and full of tradeoffs. The HN thread version skips to indignation: "they never thought of contamination so ipso facto all the research is suspect"<p>(to go a bit further, in case it's confusing: both you and I agree on "<i>why</i> do people opt-in to memunsafe code in 2026? There’s no reason to" - yet, we also understand why Linux/Android/Windows/macOS/ffmpeg/ls aren't 100% $INSERT_MEM_SAFE_LANGUAGE yet, and in fact, most new written for them is memunsafe)
You joke, but given that SWE/AI researchers literally invented AI that does everything else for them and is often super-human at intelligence across most things, I would unironically prefer the opinion of the creator of such a system over most others for most things.
Classic. This is like that female serial killer in Europe that turned out to actually just be DNA from a woman making the DNA collection swabs.
Plot twist: the woman making the DNA collection swabs was the serial killer.
Interestingly, contamination of the forensic equipment was considered early on already. However, due to the geographic area of the findings and initial negative control tests using fresh swabs, they ruled it out.
When your methods get really sensitive, you stop just measuring the world and start measuring your own process too
I thought that exact thing and opened the comments to see you’d already commented with it.<p>There is a “case files” podcast on it that I found quite good.
They weren't DNA collection swabs, but sterile swabs intended for medical use.
That’s why you’re supposed to submit an unused swab with the samples, so that they can make sure the swab itself isn’t the source.
The various "OMG MICROPLASTICS" studies always smacked of alarmism. No one has actually identified tangible harms from microplastics; it's just taken as a given that they are bad. So this fueled a bunch of studies that tried to find them everywhere. Even the authors of <i>this</i> study go to great pains to not challenge the dogma that microplastics are existentially terrifying. So I fully expect we'll still be panicking over vague, undefined harm whenever we find microplastics somewhere.<p>This type of research requires very little creativity or study design -- just throw a dart in a room and try and find microplastics in whatever it lands on. Boom, you get a grant for your study, and journalists will cover your result because it gets clicks. Whenever this type of incentive exists, we should be very skeptical of a rapidly-emerging consensus.
So, I think that while it's true that we haven't really demonstrated any tangible harms of microplastics, and there is a lot of alarmism around it, I think the concern is more rational than it might appear.<p>If it's true that microplastics are everywhere and in everything (which maybe that's now not actually the case), even a very small chance that there's some serious harm we're not aware of should be taken extremely seriously, because at this point there's (apparently) no practical way to avoid or get away from them, or to even stop producing them. And since they're such a new phenomenon in these quantities, we haven't really had the time to really drill down and figure out *if* there are longterm negative effects.<p>IMO, we should be intellectually humble about our lack of knowledge on these microplastics, and part of that humility should involve being cautious about introducing them to our bodies and environment.
> and part of that humility should involve being cautious about introducing them to our bodies and environment.<p>What does that look like today, pragmatically speaking?
asking, for all tasks shown to introduce large amounts of microplastics in our bodies and environment, "can we accomplish this task in a way that doesn't introduce microplastics in our bodies and environment"?<p>For example, using a reusable metal gourd instead of plastic water bottles for the task of 'portable hydration'.<p>and because this is Hacker News, I'll kindly welcome the comment: 'well actually metal gourds have some toxic substance in the lining that's worse than microplastics' and reply: ok, Cardboard bottles then. Or a gourd made of a sheep's bladder like back in the good ol' days, whatever they used back in the bronze age.
We aren't really looking. In the most well known case we were able to identify they were killing salmon because the salmon were dieing and worked back from that, not because some study led there first.<p><a href="https://www.ehn.org/toxic-tire-chemicals-threaten-salmon-as-nations-debate-plastic-pollution-treaty" rel="nofollow">https://www.ehn.org/toxic-tire-chemicals-threaten-salmon-as-...</a>
That is a case of a specific chemical in tires, not microplastics generally, or even rubber tire particles generally.
Isn't [bad thing is happening] let's work backwards and find [difficult to find cause] a really solid approach?
Look up on fish and the consequences of microplastics on water animals. From starvation to sex change, microplastics wreak havoc there.<p>Just because you as a single consumer may not seem impacted by microplastics does not mean it's alarmism to suggest that it's a really bad phenomenon.
Beware of the confirmation bias, it works both ways. Reporting might be alarmist (it always is), actual research is largely not. This study doesn't discredit the entire field, it's pretty obvious that microplastics are everywhere and different types are harmful to an unclear extent, even if the amount might be overestimated in some studies.<p><i>>This type of research requires very little creativity or study design -- just throw a dart in a room and try and find microplastics in whatever it lands on. Boom, you get a grant for your study</i><p>Precisely, and mapping of that kind is entirely valid and required in huge amounts to have the full picture. Somebody has to do the grunt work.
> Even the authors of this study go to great pains to not challenge the dogma that microplastics are existentially terrifying.<p>What great pains are they going through? The study is a discussion of measurement techniques and makes no comment on whether they are harmful because that’s irrelevant to the paper.<p>This could just as easily be a paper on how wearing the wrong type of gloves results in overestimating calcium in soil. You’re the one injecting a political agenda.
Off the top of my head, wouldn't it be super easy to expose lab rats to microplastics and measure results?<p>No way this isn't heavily studies by now.<p>Edit: found a whole meta-study in like 30 seconds of searching: <a href="https://www.frontiersin.org/journals/public-health/articles/10.3389/fpubh.2023.1103289/full" rel="nofollow">https://www.frontiersin.org/journals/public-health/articles/...</a>
I’ll breathe tires a little easier today :)<p>Hey remember what happened with BPA? That was frustrating. We saw ostensibly legitimate concern, then manufacturers telling us they got rid of it. Maybe it would’ve inspired confidence if the removal adverts came with data sheets on the replacement chemicals.
Peter Attia (I know, but I trust his ability to synthesize medical research) did a whole deep dive on this and IIRC determined that for the most part, it wasn't a big concern for anyone with remotely normal consumption patterns.
[dead]
I guess with Raman I can see this being misidentified but I do testing with FTIR at my job, although not often for microplastics and we often detect olefins and stearates and they don't seem to get confused. I didn't realize there were stearates on nitrile gloves, we'll need to be more careful of that. We are always weary of protein contamination from people, or cellulose/nylon from clothing.
This is good news, probably. We'll have to wait and see which studies replicate and which don't.
So basically the gloves that kitchen staff now must wear means we get an extra dose of micro plastics? Yikes.
Funnily, I believe the glove mandates for food prep are actually anti-hygiene.<p>Unlike bare skin, you can't really feel when your gloves are contaminated. So you are less likely to replace gloves when you should. With bare hands, you can feel the raw chicken juices on you, so it's pretty natural to want to wash your hands right after handling the raw chicken.<p>Gloves are important in medicine, but that's with proper use where doctors and nurses put on new gloves for every patient. That doesn't always happen.
> <i>So you are less likely to replace gloves when you should.</i><p>To the contrary. You take off and throw out your gloves every time you finish doing something with raw meat. It's procedure. It's habit.<p>You're never relying on "feel" to determine whether there are "raw chicken juices on you". Using "feel" is not reliable.<p>I don't know why you think food service workers aren't constantly putting on new gloves, but doctors and nurses are. Like, if you're cutting up chicken for an hour you're not, but if you're moving from chicken to veggies you <i>absolutely</i> are.
> I don't know why you think food service workers aren't constantly putting on new gloves, but doctors and nurses are. Like, if you're cutting up chicken for an hour you're not, but if you're moving from chicken to veggies you absolutely are.<p>I think that because I was a food service worker and it's impossible to change gloves during a rush. Nitrile gloves and sweaty hands simply do not mix. There are also many more forms of cross contamination than just raw meat to cooked food.
> I don't know why you think food service workers aren't constantly putting on new gloves...<p>I've seen enough absent-minded nose wipes on the back of gloves at Chipotle-style establishments to be pretty OK with this take.<p>And that's where people are <i>watching</i>.
Many food service workers don't use gloves and don't wash their hands after going to the toilet, from what I have observed.
> To the contrary. You take off and throw out your gloves every time you finish doing something with raw meat. It's procedure. It's habit.<p>You are supposed to. I've seen plenty of fast food places where the gloves stay on between jobs.<p>I'm sure there are upscale places that are better on this point.<p>> You're never relying on "feel" to determine whether there are "raw chicken juices on you". Using "feel" is not reliable.<p>If you were just working with raw chicken, that slimy feeling on your skin is a pretty good motivator for most people to immediately wash their hands. It's more than just procedure or habit, your hands feel dirty and you want to wash that off.<p>> I don't know why you think food service workers aren't constantly putting on new gloves, but doctors and nurses are. Like, if you're cutting up chicken for an hour you're not, but if you're moving from chicken to veggies you absolutely are.<p>You absolutely are supposed to. But there's a gap in what you are supposed to do vs what actually happens in practice. Especially if you get a penny pinching boss that doesn't like wasting money on gloves.<p>That doesn't happen so much in medicine because the consequences are much higher. But for food? Not uncommon. There are more than a few restaurants with open kitchens that I've had to stop eating at because employees could be seen handling a bunch of things with the same set of gloves on.<p>It also does not help that food is often a mad rush.
Food safety regulations in most states require that food workers replace gloves if they handle raw meat and switch to other foodstuffs.<p>But they don't generally require them to replace gloves between batches of (the same kind of) meat, or between different kinds of vegetables, or when switching from vegetables to meat, or between customers if they're on a service line. While it's recommended in those situations, I'm not sure any state mandates it.
People also don't develop good habits and constantly touch their face with gloves. I worked with surgeons in the hospital and they would point this out. Equally important in a cleanroom.
Yes but most people find it icky and would complain, especially if it's visible behind the counter. Customer is king... I can also imagine it helps with legal liability, "but we were so careful, we even mandated gloves!"
Yeah, that's more the problem than anything else.<p>And it's true that you would get cleaner food prep if you used gloves properly. However, that requires a lot of gloves getting thrown away.
Uh yea. That’s why most places use washed hands not gloves.<p>I’ve never seen for example sushi portrayed with anything but bare hands
Sushi chefs spend years learning the correct feel of the fish - when it's warm enough, when it's slimy. Japanese are taken aback when they are forced to wear gloves for "safety", which at least in that case is entirely counter productive.
It says similar.<p>“ Stearates are salts, or soap-like particles. Manufacturers coat disposable gloves with stearates to make them easier to peel from the molds used to form them. But stearates are also chemically very similar to some microplastics, according to the researchers, and can lead to false positives when researchers are looking for microplastic pollution.”<p>Stearates aren’t microplastics. Maybe we need to be concerned with stearate pollution too.
Stearates are considered very safe chemical compounds. They are derived from stearic acid which is one of the most common fatty acids and metal ions such as sodium and magnesium. Sodium stearate is a common soap and magnesium stearate is one of the most common additives in pharmaceuticals. This means that they are practically everywhere and but also easily digested in small amounts.
I'm still not aware of any reason to worry about micro plastics. As far as I know they seem harmless?
It is true that there is not currently conclusive proof that micro plastics are a significant risk to human health. However, this is the same line the tobacco industry used for decades even though they knew different.
And indeed there is not currently conclusive proof that WiFi is a significant risk to human health. However, this is the same line the tobacco industry used for decades even though they knew different.
Because it’s an inverted claim of falsification it works for literally anything (I cannot prove that X will absolutely not hurt you), but you get pilloried if you put something in the blank that the herd happens to support.<p>We’ve reached the absurd point where all sides of the political spectrum have sacred cows, <i>and</i> an exceedingly poor understanding of scientific reasoning, and all sides <i>also</i> try to dunk on the others by claiming scientific authority.
Is there any specific evidence that they are a risk to human health?<p>I mean, I get the instinct that foreign-entity can't exactly be <i>good for me</i>, but the same instinct applied to GMOs, and as far as I know organic foods have never yielded any sort of statistically visible health impacts.<p>Plastics earn their keep in general by being non-reactive and 'durable', so it's not entirely shocking if they can pass through (or hang around inside) the body without engaging in a lot of biochemical activity.
I get your point that plastics are relatively inert and may not cause noticeable harm (depending on quantity?), but I think it'd be wise to be cautious. See for example <a href="https://en.wikipedia.org/wiki/Plastic#Bisphenol_A_(BPA)" rel="nofollow">https://en.wikipedia.org/wiki/Plastic#Bisphenol_A_(BPA)</a> .<p>I'd also consider plastic, and their additives, to be a lot bigger and longer lasting unknown than GMOs.
Yeah, they gum up cellular workings. Kind of like how macro plastics will gum up turtle stomaches.<p>I have seen zero evidence that they are bad in very small quantities, but the dose can make the poison and they are out there in increasingly alarming quantities.
Many negative health effects have been associated with microplastics and related chemicals. Not sure if there's yet anything causative, but I think it's probably a matter of time and there's lots of research to be done. I'd bet the health effect of microplastics (or anything that human body isn't used to) is more likely to be negative than not.
I think any time a new material starts to meaningfully accumulate in our bodies, our food sources, our oceans, etc, we should at least go with caution. The default stance should be caution, not fearlessness.
>fearlessness<p>More like flippancy, even hubris.<p>The approach you advocate is essentially the EU's <i>precautionary principle</i>. [1]<p>[1] <a href="https://eur-lex.europa.eu/EN/legal-content/summary/the-precautionary-principle.html" rel="nofollow">https://eur-lex.europa.eu/EN/legal-content/summary/the-preca...</a>
The problem isn't just the plastics themselves. Plastics are chemical "sponges" that will soak up pollutants over time from the environment (brominated fire retardants, bisphenols, PBCs, pesticides, phthalates, heavy metals, etc) and deliver them in a concentrated dose into the body.<p>Even if plastics of all sizes are 100% biologically inert, they're still a Trojan Horse for other toxins.<p><a href="https://www.sciencedirect.com/science/article/pii/S0304389420319026" rel="nofollow">https://www.sciencedirect.com/science/article/pii/S030438942...</a><p><a href="https://www.researchgate.net/profile/Verla-Wirnkor-2/publication/335395730_Microplastic-Toxic_Chemical_Interaction_A_Review_Study_on_Quantified_Levels_Mechanism_and_Implication/links/5e762a2592851cf2719bf694/Microplastic-Toxic-Chemical-Interaction-A-Review-Study-on-Quantified-Levels-Mechanism-and-Implication.pdf" rel="nofollow">https://www.researchgate.net/profile/Verla-Wirnkor-2/publica...</a><p>Roughly 50% of indoor dust is composed of microplastics, so it's not like it's uncommon.
<i>>Roughly 50% of indoor dust is composed of microplastics, so it's not like it's uncommon.</i><p>I highly doubt that. Soil, skin and pollen are usually the big ones. Hairs depending one how you count dust, but eliminating hair like fibres would also eliminate most of the sources of plastic, unless you allow really large particle sizes.<p>[edit] Checking research. The highest claim I found was 39% of fibres (in household dust, Japan). but that seemed to be per particle not by volume.
Synthetic fibers from clothes are microplastics, and clothes shed lots of fibers. Not to mention all the upholstered furniture, carpet, rugs, drapes, bags, etc.
Instant corrective upvote.<p>One of the sources of intentionally manufactured microplastics are known as porous polymers in fine mesh sizes.<p>This is over a $1 billion market and growing.<p>One of the pharmaceutical uses is precisely as a medium to deliver oral medications in a time-release way.<p><a href="https://www.linkedin.com/pulse/porouspolymer-bead-real-world-5-uses-youll-actually-2cyvc" rel="nofollow">https://www.linkedin.com/pulse/porouspolymer-bead-real-world...</a><p>These porous polymer powders consist entirely of microscopic little sponges where they soak up and/or leach out all kinds of chemicals more so than the plain polymer, and with different affinity too.<p>However, even when common waste plastic particles themselves are not microscopically porous, different plastics soak up different chemicals to different degrees depending on what type of contact they come into. For instance kilos of polyethylene nurdles floating in the water will actually become "soaked" with some hydrocarbon liquids that are also floating or dissolved in the water. Even physically softened. These are very solid pea-sized beads that are not <i>micro</i>-sized plastics at all. They would have to degrade a whole lot before they fall into the micro category. And they are not manufactured to intentionally have a <i>nano</i>-porous structure like the finer mesh porous polymer powders.<p>Chemicals and plastics just don't go away so safely every time.
> So basically the gloves that kitchen staff now must wear [..]<p>Genuine question: we used to simply wash our hands well before preparing food.<p>At what point did the wearing of disposable gloves become "better"?
The stearates aren't microplastics, they aren't polymers, but they have chemical/spectroscopic similarity that results in them confusing the microplastics assays.
In the article it explains that what they release are not microplastics
How tricky the whole topic is
No: <a href="https://news.ycombinator.com/item?id=47563392">https://news.ycombinator.com/item?id=47563392</a>
This study assumes everybody is oblivious to contamination, and explicitly says they can't differentiate. Not useful and bordering on the tautological
I had always assumed there was a methodological failure that kept getting replicated. There were enough articles like "scientists find microplastics at bottom of peat bog" that really made me dubious of the claims.<p>"Strong claims require strong evidence". Somehow it happens pretty regularly in academia that only one method becomes acceptable and any conflicting results get herded out on technical grounds.
"The researchers used air samplers which are fitted with a metal substrate. Air passes through the sampler, and particles from the atmosphere deposit onto the substrate. Then, using light-based spectroscopy, the researchers are able to determine what kind of particles are found on the substrate.<p>Clough prepared the substrates while wearing nitrile gloves, which is recommended by the guidance of literature in the microplastics field. But when she examined the substrates to estimate how many microplastics she captured, the results were many thousands of times greater than what she expected to find."<p>------------------<p>The very first thing that should have been done is to run results for a substrate that <i>hadn't</i> been placed in the sampler. You <i>need</i> to know what a zero result looks like just to characterize your setup. You'd also want to run samples with known and controlled micro-plastic concentrations. Why didn't they do this? Their results are utterly meaningless if they didn't.
That does seem like an oversight. We routinely run process blanks for elemental analysis at my job. I guess if the metal substrates had specifications on no particles you might skip this, obviously a big mistake if another step (ie. handling with gloves) introduced contamination.<p>In surface science the baggy clear polyethylene are widely known to be cleaner than other options.
Yeah, where is their control sample without any substrate on the sampler?
They found microplastics in the snow in Antarctica and in human embryos right? So this seems rather redundant.
Reminds me of the story of Polywater. <a href="https://en.wikipedia.org/wiki/Polywater" rel="nofollow">https://en.wikipedia.org/wiki/Polywater</a>
The way this study was done makes perfect sense for finding this cross-contamination issue, but does not actually address how microplastics samples are extracted and found in sampling studies.<p>The below meta-study largely discusses sampling methods and protection from cross contamination so everyone here acting like this one study’s somehow invalidates decades of quality research:<p>>Due to the wide contamination of the environment with microplastics, including air [29], measures should be taken during sampling to reduce the contamination with these particles and fibers. The five rules to reduce cross-contamination of microplastic samples are: (1) using glass and metal equipment instead of plastics, which can introduce contamination; (2) avoiding the use of synthetic textiles during sampling or sample handling, preferring the use of 100% cotton lab coat; (3) cleaning the surfaces with 70% ethanol and paper towels, washing the equipment with acid followed by ultrapure water, using consumables directly from packaging and filtering all working solutions; (4) using open petri dishes, procedural blanks and replicates to control for airborne contamination; (5) keeping samples covered as much as possible and handling them in clean rooms with controlled air circulation, limited access (e.g. doors and windows closed) and limited circulation, preferentially in a fume hood or algae-culturing unit, or by covering the equipment during handling [15], [26], [95], [105], [107]. A fume hood can reduce 50% of the contamination [105] while covering samples during filtration, digestion and visual identification can reduce more than 90% of contamination [95].<p>So don’t ghost ride the whip about the death of the microplastic plague just yet.<p><a href="https://www.sciencedirect.com/science/article/pii/S0165993618305247" rel="nofollow">https://www.sciencedirect.com/science/article/pii/S016599361...</a>
the_plastic_detox documentary on netflix promotes the idea that microplastics cause infertility. this is based on 6 couples 90 days experiment.<p>they tracked levels of plastic-related chemicals and fertility markers.
after plastic detox 3 out of 6 couples got pregnant.<p>the whole research process methodology, not just measurement, miss critical assessment
So the takeaway is: we've been accidentally adding "microplastics" with the very gloves we use to avoid contamination. That's almost poetic
Stearates aren’t microplastic plastics, though, they’re just similar enough under a microscope and in some chemical analyses. Without knowing which stearates glove manufacturers use (or what exactly it is about microplastics that is harmful), it’s difficult to to say whether the stearates will have the same harmful effects.
While we are used to associate "the observer effect" with particle physics, it can appear in biology and/or chemistry as well.<p>Keeping things meticulously clean on the microscopic level is a complicated task. One of the many reasons why so few EUV chip fabs even exist.
Finally some good news.
Good news with a note:<p>> That’s not to say that there is no microplastics pollution, the U-M researchers are quick to say.
>
> “We may be overestimating microplastics, but there should be none. There’s still a lot out there, and that’s the problem,”
Didnt they use for newest studies to detect microplastic in placentas I think only non plastic omitting alternative gloves and material. Can't recall there it was specifically mentioned in a worldclass ARTE docu about microplastics maybe some ARTE Ultras here can recall.
this feels like such a weird oversight in such a controlled environment: "oh my bad it was the gloves!"
I wonder in how many other studies this happened?
A rediscovery...six years later:<p>"When Good Intentions Go Bad — False Positive Microplastic Detection Caused by Disposable Gloves" - <a href="https://pubs.acs.org/doi/10.1021/acs.est.0c03742" rel="nofollow">https://pubs.acs.org/doi/10.1021/acs.est.0c03742</a><p>From the study in the OP you cannot derive that current studies on microplastics are not valid. The headline framing that scientists have been measuring their own gloves, is science journalism doing what it does best...<p>Stearates are water soluble soaps, so any study using standard wet chemistry extraction, and that is most of them, washes them away before analysis even begins. Stearates also cant mimic polystyrene, PET, PVC, nylon, or any of the dozens of other polymers routinely found in environmental and human tissue samples.<p>Nothing to see here.
Called it!<p><i>> To be honest, after reading some of these microplastics papers I'm starting to suspect most of them are bullshit. Plastics are everywhere in a modern lab and rarely do these papers have proper controls, which I suspect would show that there is a baseline level of microplastic contamination in labs that is unavoidable. Petri dishes, pipettes, microplates, EVERYTHING is plastic, packaged in plastic, and cleaned using plastic tools, all by people wearing tons of synthetic fibers.<p>> We went through this same nonsense when genetic sequencers first became available until people got it into their heads that DNA contamination was everywhere and that we had to be really careful with sample collection and statistical methods.</i> [1]<p>[1] <a href="https://news.ycombinator.com/item?id=40681390">https://news.ycombinator.com/item?id=40681390</a>
I haven't really read the studies but shouldn't they have negative controls to negate these effects? Wouldn't that let the author's correct for a baseline contamination level in the lab?
That was the difficulty with DNA: how do you make that control if everything is contaminated and minor variations in protocol (like wafting your hands over the samples one too many times) changes the baseline?<p>It took years to figure out proper methods and many subfields have their own adjusted procedures and sometimes even statistical models. At least with DNA you could denature it very effectively, I’m not sure how they’re going to figure out the contamination issue with microplastics.
I have worked at a sequencing center before. DNA contamination is easier to mitigate because the lab disposables aren't made out of what you are testing. Disposables are almost always plastic and tend to have minimal DNA contamination. Environmental DNA contamination is largely mitigated with PCR hoods and careful protocols/practices. However, these procedures don't mitigate DNA contamination at the collection level, which is likely where the statistical models you mentioned help.<p>I can't imagine wafting your hands over the tubes would change the plastic amounts substantially compared to whatever negative controls the papers used. But again, I am not an expert on this kind of analytical chemistry. I always worry more about batch effects. But it does seem like microplastics are becoming the new microbiome.
On the one hand, hundreds or perhaps thousands of studies might be wrong. On the other hand, this one might be wrong. Who's to say?
That has happened many times in scientific research. The aforementioned fad in DNA sequencing was one such case where tons of papers before proper methods were developed are entirely useless, essentially just garbage data. Another case is fMRI studies before the dead salmon experiment.
Not even that! This study doesn't even say contamination <i>is causing</i> overestimation. It says that it's possible.<p>But as mentioned elsewhere in the thread, everyone knows that it's possible and take measure to mitigate it.<p>A paper that said those mitigations were insufficient or empirically found not to work would be interesting. A paper saying "you should mitigate this" is... not very interesting.
> Not even that! This study doesn't even say contamination is causing overestimation. It says that it's possible.<p>From the article:<p>> They found that on average, the gloves imparted about 2,000 false positives per millimeter squared area.<p>I dunno, that seems like a lot of false positives. Doesn’t that strongly imply that overestimation would be a pretty likely outcome here? Sounds like a completely sterile 1mm^2 area would raise a ton of false positives because of just the gloves.
The way you mitigate this is by using negative samples. Basically blank swabs/tubes/whatever that <i>don't</i> have the substance you're testing in it, but that is handled the same way.<p>Then the tested result is Actual Sample Result - Negative Sample Result.<p>So you'd expect a microplastic sample to have 2,000 <i>plus N</i> per mm^2, and <i>N</i> is the result of your test.
> Plastics are everywhere in a modern lab and rarely do these papers have proper controls, which I suspect would show that there is a baseline level of microplastic contamination in labs that is unavoidable. Petri dishes, pipettes, microplates, EVERYTHING is plastic, packaged in plastic, and cleaned using plastic tools, all by people wearing tons of synthetic fibers.<p>Maybe so, but plastics are also everywhere in our daily lives, including on the food we eat and in the clothes we wear. As we speak I just took some eggs out of a plastic carton, unwrapped some cheese from plastic wrap, and got oatmeal out of a plastic bag. The socks and pants I'm wearing are made of polyester.<p>If plastics cause contamination in a lab, would you not also expect similar contamination outside of the lab?
You would, but if you do studies that claim that microplastics accumulate in our bodies or even in out brains it makes a difference.
I think you underestimate how much plastic is consumed in a lab doing experiments or analysis. I suspect it's an order of magnitude or two more than people are regularly exposed to at home or other non-industrial settings.<p>When I was an automation engineer at a lab, each liquid handler alone could go through several pounds of plastic pipette tips in a single day. All of that is made out of plastic and coated in a different thin layer of plastic to change the wettability of the tip. Even the glassware often comes coated in plastic and all these coatings are the thin layers most likely to create microplastics from abrasion (like the force of the pipette picking up the tip!). Throw all the packaging on top of that and there is just an insane amount of plastic.<p>The only place I've seen more plastic consumed is industrial and food manufacturing where everything is sprayed and resprayed with plastic coatings to reduce fouling.
> That’s not to say that there is no microplastics pollution, the U-M researchers are quick to say.
>
> “We may be overestimating microplastics, but there should be none. There’s still a lot out there, and that’s the problem,”
shouldn't you be particularly attentive to your bias then? an article came out that _seems_ to confirm your previous belief that you arrive at without really testing? like everyone itt that is looking like the comments of an steven crowder comment section in a post about climate change
ITT people that only read the headline.
[dead]
[flagged]
[flagged]
[flagged]
> The authors acknowledge funding from the College of Literature, Science, and Arts at the University of Michigan. R. L. P. was supported by an NSF Graduate Research Fellowship (NSF-GRFP) DGE-2241144. M. E. C. was partially supported by the University of Michigan Rackham Graduate School through a merit and predoctoral fellowship. The authors would like to acknowledge the professors and students of the Mapping, Measuring, and Modeling Microplastics in the Atmosphere of Michigan team for their support and helpful discussions. The authors thank Jennifer Connor, Curtis Refior, Amy Pashak, Megan Phillips, Josh Hubbard, Bill Joyce, and David Lee for their community partnership. The authors would also like to thank former Dean Anne Curzan from the College of Literature, Science, and the Arts at the University of Michigan for funding this work through the “Meet the Moment” grant program. The authors acknowledge technical support from the Michigan Center for Materials Characterization.<p>Is there anything wrong here? Not sure I understood your comment
Who?<p>> The authors acknowledge funding from the College of Literature, Science, and Arts at the University of Michigan. R. L. P. was supported by an NSF Graduate Research Fellowship (NSF-GRFP) DGE-2241144. M. E. C. was partially supported by the University of Michigan Rackham Graduate School through a merit and predoctoral fellowship.
Where do I find this info?
In the acknowledgements section. However, after reviewing it, I’m not sure what or who I should be looking for, so I’m not entirely sure what the OP is hinting at.<p>At first glance, nothing appears suspicious, though I should note that I’m not familiar with any of the authors and haven’t looked into them further.
So the problem is these particles are literally flying off the gloves of the scientists wearing them to the point it's interfering with the experiment and so... it's less of a problem?
No, the gloves leave stearates (not plastic, but similar looking particles) residue on contact. So there are not literally micro plastics flying off the gloves. Read the article.
It's not microplastics coming from the gloves. It's particles of the powder used to coat the gloves and keep them from sticking. Different composition, but similar and easily mistaken.
Well, it could mean more microplastics occur in an unnatural environment (the lab) containing much more plastics than in a typical home setting.<p>If you're around plastic a lot you're ingesting a lot and if you're not, you're not.<p>So the conclusion would be that plastics "sheds" and you should avoid it in packaging, kitchen utensils, etc
Yes? Most people don’t live their entire lives in a lab wearing nitrile gloves, so there’s an argument to be made that the concentration of microplastics found in that setting is not reflective of everyday life.<p>So, not that microplastics don’t exist, but that they don’t exist to the same degree as in a lab environment.
I wouldn't be surprised if e.g. all these paper-thin synthetic (plastic) disposable parts and fabrics used in labs shed microplastics way more than e.g. synthetic fabrics designed to be survive a machine wash a few dozen times, or upholstery meant to withstand tens of thousands of sitting cycles, nevermind solid plastics (e.g. reusable food containers, furniture surfaces).
Huh, good point
If you read the article you'd find that what they are finding are <i>not</i> microplastics - they're stearates[1]<p>These are soap-like chemicals used as mould release agents on gloves, but what also means are chemically similar to plastics when analyzed by some techniques and under a microscope will spontaneously form micelle-structures which look very similar to microplastics (you can't exactly get in there and poke them).<p>[1] <a href="https://en.wikipedia.org/wiki/Stearic_acid" rel="nofollow">https://en.wikipedia.org/wiki/Stearic_acid</a>
As per usual, they get the result then go back to do the study.
Been happening in economics forever too.
So you're saying microplastics aren't a problem, because there's too much microplastics in gloves??
If you the read article, you would see it explains that what they release are not microplastics. They are instead a soap used to get them to unstick from their mold in production.
I don't see anyone saying they aren't a problem.
That's a relief. Now I can stop worrying about microplastics. Just like the environment - we don't hear much about it any more, so they must have sorted that out too. Didn't they? Did they?
Carl Sagan was right all along. Always question science, never trust these so called experts, do your own assessment, research and thinking. This must be another global climate change scam.
It is partially correct. Except make sure you have the necessary skills to question the science. Intuition in these things are quite misleading. Don't start questioning cancer reports just because you don't feel sick.If you really don't trust it, get a relevant medical degree or take second opinions from those who are really qualified and not some quacks. Otherwise you would just end up dead.
I guarantee you Carl Sagan was not telling you to dismiss experts and he very much understood climate change was real. He literally testified before Congress on it, likely decades before you were even born.<p>It is generally bad practice to so drastically twist somebody’s words to make them say the opposite of what they’re saying. Carl Sagan would not agree with you.
Weaponized ignorance.
> Do your own assessment.<p>Yeah, and my primitive home-grown analysis then carries the same weight as those from experts with professional equipment? Oh come on...
Doesn't have to be one or the other. Trust, but verify? Experts make mistakes, professional equipment can be mishandled. Don't take anybodies word, look at the evidence for yourself.<p>This is a very scientific way of thinking. It's only gotten a bad rap on account of people using it to attack others' research and then(crucially) failing to perform their own.
> Don't take anybodies word, look at the evidence for yourself.<p>Please nobody listen to his person. There is nothing scientific about ignoring the experts to instead behold the opinions of the uninformed.<p>The world is too large, too complex, and too nuanced for the layman's opinion to be worth much. When someone is unqualified treat their opinion as equal to every other unqualified persons opinion. Include your own in that assessment. Be honest, what qualifications do you have that make your assessment of the evidence more valid than any other random street person's in the given field? It's very likely the answer is "none". So lend your own opinion the level of respect it has earned. Be honest with yourself about what that level is.<p>"There is a cult of ignorance in the United States, and there has always been. The strain of anti-intellectualism has been a constant thread winding its way through our political and cultural life, nurtured by the false notion that democracy means that 'my ignorance is just as good as your knowledge.'”
― Isaac Asimov
> The world is too large, too complex, and too nuanced for the layman's opinion to be worth much.<p>This has a very, "Trust us, we're with the government." feel to it.<p>I enjoy Asimov's writing immensely but if you think quotations are some kind of mic drop, I'll leave you with this one.<p>"The question then is not whether or not a girl should be touched. The question is merely where, when, and how she should be touched" ― Isaac Asimov
I am right and I suspect you know it... you just don't like the way it makes you feel. Hence your focus on vibes and ad hominums rather than reason.<p>It is self evident that moderm science is too complex for the average person to understand, and fifty percent of us are less intelligent than even that.
True, trust but verify and start questioning things. Science is now more politicized more than ever by politicians. COVID vaccines are not even tested. I didn't said this. Pfizer and Moderna CEO said this in EU parliament hearing.
The claim wasn’t it wasn’t tested but that it wasn’t tested for transmission prevention.<p>Still false<p><a href="https://www.rmit.edu.au/news/factlab-meta/viral-pfizer--admission--not-what-it-seems" rel="nofollow">https://www.rmit.edu.au/news/factlab-meta/viral-pfizer--admi...</a>
Lol, the COVID vaccines went through some of the largest randomized controlled trials ever conducted and had some of the best safety and efficacy results ever seen.<p>You might have heard that it wasn't tested for <i>reducing transmission,</i> i.e. whether the vaccines make it less likely that an infected, vaccinated person would transmit the virus to someone else... Which it wasn't, because uhhh... how would you?<p>They tested it for safety, reduction in symptomatic infection rate and reduction in infection severity.<p>You should set aside your conclusions for a bit and take an earnest effort at learning some of the details of this stuff if you want to "do your own research" etc. It is clear you are misunderstanding some pretty fundamental things that are actually easily understandable if you approach them with honest curiosity!<p>You can literally look up the trial designs and they just say right on them exactly what they're testing for and how they're doing it.
>> <i>COVID vaccines are not even tested</i><p>Do you have a link to the exact quote?<p>IIRC they have a 95% reduction in hospitalization rate, measured in a double blind human trial. [Compare that with the vector virus and inactivated virus vaccines, that have like a 65% reduction in hospitalization rate, measured in a double blind human trial.]
We have more data on COVID vaccines that nearly every drug in existence.<p>My wife was one of the first pregnant women to get the vaccine (outside of trials) because she’s an ER doctor, and she’s had regular follow-up surveys from the CDC for years.
I assure you, you do not have the background to properly assess the research.