Hey there, everybody, it's Josh and for this week's select, I've chosen our June of twenty twenty one episode on slime Mold. It's actually a powerhouse episode and it's filled with maybe more amazing facts than any other episode we've ever recorded. It's just like mind blow after mind blow after mind blow. So strap on your old timey football helmet and prepare for slime Mold. I really think you're going to enjoy it.
Welcome to Stuff You Should Know, a production of iHeartRadio.
Hey, and welcome to the podcast. I'm Josh Clark. There's Charles W. Chuck, Wayne Bryant, and this is Stuff you should Know. No producer edition, that's right, it's just us, buddy, We're going to do it. We're going to be just fine.
Jerry took an early vacation for Memorial Day.
I know she's always doing stuff like that.
She knows how to live, and we're stuck with slime Mold in her absence.
I like slime Mold.
I knew you would love slime Mold.
Uh yeah, I think it's pretty interesting stuff.
It's very Josh Clarky.
It is kind of Josh Clarky so much so that as I was researching this, like, I mean, I just kind of generally knew about slime mold that it exhibited, you know, some weird level of intelligence here there, but I didn't know much about it. And then as I was researching, I was like, I'm kind of into slime mold now, Yeah, like all the different kinds of it. I like regressed into like, you know, the nerdy eight year old I never was.
Yeah, and then you're like, let me clark this over to Chuck and see what he thinks. Yes, yeah, I like slimold too. I think it's kind of cool.
Let's do it, Okay, Chuck, I'm ready. All right, everybody stand back because we are doing it.
Yeah, and I think you could file this. I mean, it's not an animal slime mold. I guess we should just tell you right away. It's not an animal. It's not a fungus, even though you would think it's a fungus if you saw it on the forest floor. And we'll get to all this stuff, but it feels like an animal one of our animal episodes anyway, sort of.
Yeah, I was gonna say the fact that it's not an animal or fungus or at the very end, but sure we could do it at the beginning, I guess.
I mean, like literally in the last minute they were like, I still don't know if this is an animal? Is it a dog in disguise?
You know everything we just told you about. It's not an animal, it's not even a fungus. And then we just go to listener mail.
So what is it though, besides super ancient as in like maybe one of the very first living things.
Well, it's a protest, actually, they figured out, and protest seems to be well, it's one of the five main Kingdom's animal bacteria, plants, fungi, and then protests and protusts are typically single celled organisms like a meba, yeah, or protozoans things like that, and they have I couldn't find out exactly when they did it, but they fairly recently, I guess in the history of biology, fairly recently reclassified slime molds from the Kingdom fung guy over to the Kingdom protista.
Yeah, which is interesting because for years they had been studied by mycologists who were fun, fun guys. Yeah, And they found out later they were like you know what, sorry, they should really go over to the protostologists and they said, we kind of like these guys, Can we keep studying them since we have been? And they said sure, And the protostologists were superbist.
They were, they were. They're still actually not over it. They're frequently tpeeing the academic halls of the mycologists whenever they get the chance.
Yeah, it's just very bitter battle.
So that is pretty cute that that the fung guy people are still are still studying slime molds even though they're not fung guy. But there's you know, some good reas is why they were originally considered to be fungi, Mostly that they're like these big kind of clumps, and there's all sorts of different ways that they take shape and form depending on the species. They're different colors, some of them form kind of netlike honeycomb structures. Some of
them look like dog barf. One of the main ones we'll talk about today looks a lot like dog barf.
They look like a fungus though, Like if you were walking in the woods and you saw this, nine out of ten people would say, well, it's got to be some kind of fungus.
Yeah, especially because if you're staring at them. You would have to stare at them for about five, six ten hours to see that they have a huge difference between them and fungi, and that they move. They just move so slowly it's not apparent to the naked eye. But if you film these things with time lapse cameras and speed it up, you can see all they very clearly move about from place to place. So that's a big
differentiator between them and fungi. But one of the reasons they thought they were like funger, that they were funger is because they produce spores to reproduce.
Right, And I mentioned their ancient origins. They are about a billion years old, and like I said, could be like as soon as there was stuff, it seems like there was slime mold eating basically eating the bacteria that breaks down other stuff that dies, and that's what they feed on. Bacteria, mold, yeast, basically anything that decomposes dead things, slime molds in Gulf. I think it's it's not called photography, it's called figotrophy.
Oh yeah, it's not how I was going to say it. But are you going to say fego travo trophy? Yeah, but I think you're absolutely right.
Well, you know us, it wouldn't be ues if we didn't probably both get it wrong, right, But that's when you basically surround something and engulf it and just sort of like move it into your body just like sort of absorb it basically.
Yeah, which is another difference between slime molds and fungi, because fungi actually break the food down and then absorb the broken down nutrients. But the fact is, if you have things that are decomposing, other things like bacteria, molds, yeast, the things that crawl onto or grow on dead people, dead trees, all that stuff break them back down into
their constituents. So the fact that this slime mold feeds on other things, it makes it a really important part of the food web sure, as part of the nutrient cycle, because other things come along and eat the slime molds. There's apparently a kind of beetle that has a specialized jaw that allows it to slurp up slime molds. I think some kinds of insect larva eat them, and then so it just kind of keeps going. But they're a really important part where you just have these microbes that
like the beetle couldn't get to that. They're able to basically get that energy from you know, the bacteria by eating the slime molds.
Right, And even though other protists can carry disease, slime mold is quite human friendly. Actually, you can eat the stuff if you want. There's a dish in Mexico, in some parts of Mexico called Coca de Luna, which is exactly what you think it is. Yeah, poop of the moon,
moon poop, yep, and they eat the stuff. I even looked online to try and get a good recipe, but it's not on like the pages of Martha Stewart Living like it's you got to dive deep into Reddit and stuff like that to get some good recipes.
It seems like almost almost smacks of urban legend. But I'm seeing it in different enough forms yeah that I think it's probable that it actually is a thing. The thing that scares me is that people say, like in some regions of Mexico, it's like, that's not super specific, you know.
True, and we pointed out they weren't animals or plants, but we definitely need to point out that slime mold is also not mold. No as a protest.
That's right. So one of the really amazing things about slime mold is there's a couple of different kinds, as we'll talk about in a second, but a whole bunch of different kinds of species. One type of slime mold can get really big. I mean some of them can get up to the size of like a medium or pizza large pizza, I guess, depending on whether you're getting ripped off by your pizza guy. But like twelve inches in diameter. Yeah, that's enormous. Right, So you're like, well,
that's pretty cool. It's a big blob of mold. Well, put your sockgarters on, because I'm about to blow your socks right off your feet. Some of those types of slime mold that are as big as a pizza are one giant cell.
Yeah, I mean, this is truly amazing. The plasmodial slime mold, which is I guess you could call it one of the true slime mold is it has all the stuff like as if it were undergoing cellular division, and all the different nuclei, like millions of nuclei, organelles, cytoplasm, all that stuff, but it's just not it doesn't have cell walls. It's not individual little cells. It's just it splits and lives inside this giant fortress wall.
Yeah. It's almost like if you took all the cells that should have made this giant blob up as a multi cellular organism and just kind of broke them open and dumped all the contents into this blob. Yeah, and then through the cell walls away, that's what you would have.
It's super interesting.
It is, and it's it's really kind of straightforward if you just hear it. But it's also really easy to just keep going like wait, why why is it like that? And how is it like this? What's going on here? Which is one of those things that it just it makes slime mold. It's its own thing. And we're still learning about this stuff, you know, every day.
Yeah, and I mean it gets there's quite a few times in here where we're going to say, and here's where it gets even crazier.
That's right.
This isn't super crazy. But the other kind of slime mold, or the other big broad categories, the cellular slime mold, and these are lots of individ vidual, single celled organisms, but the kind of knockout fact about them is when they're stressed out, if they don't have a lot of food around, they can join up together and sort of look like one of those plasmodial slime molds, but it's not. It's called I guess pseudo plasmodial, yeah, because it's not
a real one. But it basically says, all right, we're gonna all come together to try and find food together, and then when they do have food, they can be like, all right, we'll just go along our merry way and split up.
Again, yeah, which is pretty nuts. They also will come together apparently it makes it harder for predators like those specialized beetles to eat them, because those individual slime molds can be you know, a millimeter in size or smaller. Yeah, so it's pretty easy for a beetle to eat that. It's much harder for a beetle to eat something the size of like, you know, a quarter. Right, So they actually do come together. They come together to move. They
also come together to reproduce and produce spores. But the characteristic of this that what makes it a pseudoplasmodium rather than actual true slime mold, is that they retain their cell walls, their individual cells. When they come together, they just kind of loosely formed together. And a really good way of understanding what the cellular slime molds create is kind of like a swarm.
Yeah, that's a good way to put it, I think. Or what's the uh god, that my favorite thing? When the birds do that? What's that called?
Flock of seagulls? Haircut?
Sure, that's it, boy, you threw me there. So these the plasmodium is covered by a layer of slime. And you're gonna want to put a pin in this because when they do move around, they leave behind a little these little collapse tubules and it looks basically like not exactly like a snail trail, but sort of like a layer of slime. And you're gonna want to remember that for later on because these actually kind of serve as important little markers.
As a matter of fact. Write it down, everybody. We'll wait until you get a pen and a piece of paper.
Bullover, go inside the CBS closest to you. Yeah, yeah, put on your mask by a pin. Yep, buy a piece of paper.
Pay ten twelve times what you should have paid for that pen. Really, Oh my god.
Pin markup is big at CBS.
I think the general mark up at CVS is fairly high.
Oh, they're like, we get him in here for the aspirin, then we really juice them with this ballpoint pen.
That's right. I hope there's no CVS ads in this episode, but we'll find out.
What is a what's a good deal at a drug store?
Is there like a there's zero?
Are they all mark it up?
Yeah? Everything's marked up because it's like it's like convenience kind of thing.
You sound like a lot of sound like a grandfather. It's all marked up.
Right Back in my day, you just go to a regular grocery store and buy your pens.
Well, you buy from the pin factory, straight from the man who made it. It's right, you know, when I was little, you would for a short time. I'm not sure why we did this, because it's not like we lived out in the country and this is a very
old timey country thing to do. We bought our milk direct from a farm nice and we would pull up and I would get to walk inside this huge walk in cooler, like next to a loading dock, and I just thought it was like the coolest thing in the world somehow to get that fresh milk.
Sure didn't. They back the cow up and it makes a beeping sound and they just scort the milk right into the back of your station.
Way. It's right, they mark it up first, wash your way home. So where were we? Okay? If you do see this stuff in the woods, if you ever hiking along and you see a big or medium size pizza like yellow blob or orange blob. They can be red, they can be white, they can be maroon. Very rarely, they can be black, blue, or green, but usually it's sort of yellowish an orange. And you see that in the forest, you're probably looking at a slime mold.
Yeah, especially if it's really hot out and it just rained.
Yeah, the worst thing in the world for me.
You can also see them like on your grass too. Apparently, if it gets really rainy and hot, slime molds will actually come out of the woods into your grass and be like, oh, this is pretty nice and they aren't gonna do any harm. It's not a problem for your grass. It just looks kind of gross. It's certainly not gonna hurt you or your pets. And then eventually it'll dry up and turned to kind of a gray or tam
powder and blow away. And that means that it just turned into spores and it just reproduced all over your place.
Yeah, I think maybe we should take a break because right now people are probably like, dudes, you promised greatness here, and so far it's a little hum drum.
What.
So put those salt guarters back on, because when we come back, we're really gonna start knocking them off with some of these amazing facts.
Okay, chuck, we set them up, let's knock them back down.
So here's one cool fact is that slime molds basically can do the equivalent and do the equivalent of throwing themselves on the grenade. They will sacrifice themselves to save others. And these are things without a brain or a central nervous system. Like it's not like they think, hmmm, I'm feeling empathy today for my fellow mold. Sure, and so I'm gonna save everybody because I've come across some infectious bacteria.
But what they do is they come across it, they engulf it, and then they say, let me go, and they cut themselves off from the pack, from the swarm and detach themselves and die of that infection, but save the rest of the group.
And my heart will go on played in the background as they get further and further away, exactly. But that's that's altruism, yeah, which is pretty amazing considering, like you said, they don't have a brain or anything like that. So how how are they doing this? We'll get to that later.
So what about tell everyone about the dick Dystellium diyscoitus discods discoids.
Okay, that's one of my favorite words now, discods.
Just because as disco in it.
So that this was this is a kind of cellular slime mold, right, So it's made up of a bunch of different individual organisms that come together and when they come together they practice altruism to some degree as well, because some of them will basically be like, Okay, I'm dead.
Now I'm dead. I'm going to turn into a bundle of cellulose fibers, and that cellulose is going to connect with other slime mold cells that have dyed and turned into cellulose and come together and form a stalk, and then at the top of the stalk a bunch of different slime mold cells. They're called slugs. When they're individual like that will climb up the stalk and then they'll
turn into spores. And then in that way, they're sticking up out of the ground and a passing animal will come and they'll stick to it and it'll get a ride to greener pastures. But to do that, some of them have to die to form the stalk to let the spores grow on top of which is pretty amazing itself.
It is. And you know we mentioned that they move, you know, they're not. They don't just sit around and wait for someone to drop a pepperoni near their pizza shape in the woods so they can eat it. They got to go where the food is, and they either move by these little appendages that like little feet like appendages. Those are the cellular slime molds, the individual single celled
organisms that can come together, and this is crazy. The other kind they move as one big mass because you know, there's no cell wall going on, so they just sort of expand and contract the cytoplasm to kind of gush their way along the ground very slowly.
Yeah, which is really neat to see because when they're especially when they're searching for food, which is basically all they're ever doing. Like everything that they do is either to get away from some noxious stimuli or to go toward food. Usually to go toward food. It sounds like us it basically, Yeah, I don't like that smell. Wonder we love them, but I like that smell. I'm going to go toward that. So they make these amazing kind of they look almost like seafans, you know what I'm
talking about. They look very fractally and they just kind of they fan out, is the best way to put it. When they start to go look for food, and when they do fine food, they start moving toward it. It's the cell walls contract and that cytoplasm goes that way and next you know, over a very long period of time.
See you know, five days later.
The slime mold has moved and actually sli molds. If you don't they like they they're totally fine living in petrie dishes for as long as you want them to, as long as you feed them. If you stop feeding them, they'll just get out of the petrie dish and start looking for food elsewhere.
So they'll they'll stay creepy.
Yeah, but I mean again, it's not like you're just sitting there watching this thing crawl out of it's Petrie dishes. You leave overnight and you forget to feed the thing, and you come back and it's half of it is out onto the table or something.
It's something like right out of Gremlins kind of you. And I think you said they move it about a millimeter an hour, but some of them, actually, if they're really cooking, can go about an inch and a half in an hour, which it's really fast. I mean, it doesn't sound fast, but when you're talking about what we're talking about, it is pretty fast.
Yeah, And I saw that a couple of places. Most people cite something like a millimeter an hour. Remember which one goes that fast? But yeah, I mean you can't see it moving when you're staring at it, but over time you can for sure.
Sure, or you know, if you're just really patient and you can lock in on something, you might be able to see that.
So when they started figuring out in the early two thousands of Japanese researchers were some of the first to like really study slime molds, is showing some sort of intelligence. They figure this out from you know, from watching these things actually move about and when you when you film them in like high speed and then replay it. You can see their movements are deliberate in a lot of ways. They're they're not just blind dumb movements where they happen
on to food. They clearly can sense food somehow or some way, and they spread out and they seem to spread out and again in a really deliberate way. And so some some researchers started to test slime molds to see what they were capable of. One of the first one, one of the first researchers was a Japanese scientist named Toshiyuki Nakagaki, and I think so too. And doctor Nakagaki,
which is even better. Yeah, Yeah, built a maze, like a pretty simple maze, but an actual three dimensional maze, and a good sized peatree dish put what has come to be known as probably the smartest size slime mold, Phizarium polycephalum, which is kind of like the rock star of the slime mold world these days, put a phaisarium in it and said go to town, go find your little favorite oat flake treat, which is their their favorite food. Yeah.
And the key here is is there were four different routes to two different endpoints where this food was. It wasn't just like, there's only one way to solve this maze. And so they put the little oat flake at these endpoints. And the micro organisms that grow on the oat flakes
is what they're after. It's not like they love oatmeal or anything like that, right, right, And so he put them there and studied them, and over the course of hours, these things basically learned to get to that food in the quickest, fastest way every single time.
Yeah, like it could, it could conceivably get to it, like you said, four different ways, but that fast way was the way that it would. Just like, that's impressive. That's definitely noworthy. You can write multiple papers on that kind of study. And so another Japanese researcher came along and said, hold mysake, a researcher named at Sushi Taro from Hokkaido University, did you like that?
Yeah, that's good.
And doctor Tiro said, all right, what about this. What if we take some oat flakes and basically make a general map of the neighborhoods in Tokyo and see what the slime mold does with that. Put a little slime mold in a petri dish with these oat flakes that kind of mimic the neighborhoods of Tokyo, and watched it go think over the course of like four or five days.
Right, yeah, and you might think cool, it does what it does and it goes after that food in the most direct way possible, which is what it did. But here's where it gets genuinely amazing. Is they went back and they overlaid a map of the current Tokyo railway commuter system, the subway system, and they laid it over this grid of this slime and it was almost a perfect match.
Is that nuts?
That's I mean I had to reread that like five times to even believe that that's what happened. That this slime basically figured out the most efficient route to get around essentially Tokyo.
Yes, which I mean humans had figured out too, but it took teams of human engineers and a very long time for them to figure this out. Right, So the slime mold was just like, this is nothing. What else you got? You got any more cities that are more densely populated with more neighborhoods, because I'll just make your subway maps all day long.
Basically, and they're like, nah, Tokyo is probably one of the most dense, right, Okay.
I saw another another similar kind of a bit of research chuck where they actually used oat flakes to signify ancient Roman cities in the Balkans. Wow, this is this is crazy. It's like an archaeological study. And they put some they sicked some faisarium on it and paiserum on it, and it mimicked ancient Roman roads that had been lost, were very obscure, had largely been forgotten, and ones that
were well known in the Balkans. It mimicked these these Roman roads like things that people had been like, okay, this is the best route from this city to this city. That the sli mold did basically the same thing and apparently revealed some lost stuff.
Yeah, I mean, I guess it could. Also it's interesting like if it does match up, if they do an experiment like this, does that mean like the humans get it wrong? Like can they use this as a test and be like, sorry, the slime mold is spoken.
I guess so. I kind of like the octopus picking the World Cup. You know, they always take the World Cup away if the other team that the octopus didn't right ends up winning.
You know, well, I wonder if you I mean, and we'll get to real applications of this, but I wonder if they could do something like that where they let's say they look at the Tokyo system in a couple of places it didn't match. They're like, we totally should have gone this way.
Yes, I feel like that that is the direction that people are kind of going in that they they could conceivably use this for planning new stuff.
You know, wow, so every city planner will have a slime mold researcher at their best.
Yeah, I mean, like, this is crazy. Why not? You know, all you have to do is have some oat flakes and a Petri dish and you're good. So I think we should take another break.
What do you think, I'm quite frankly we want to eat some oat flakes right about now.
I'm kind of in the mood for that too. We'll be right back. Okay, did you just see some moat flakes? I did not.
We'll get you some, because here's the secret, everybody, when we take a break, we don't really go take a break.
We should have had some crusty old oat flakes on your desk and just eating them real quick. I don't know, I can't see.
So all right, we've said that these things don't have brains. They don't have, and I don't think we mentioned that. It's not like they have. It's not like they're jellyfish and they have some sort of weird neural net, right.
They got nothing like that at all, nothing like. They have no way of generating consciousness in any form that we recognize. And yet slime mold is teaching us to open and open our horizons in hearts, to sure to new ideas of what constitutes consciousness and intelligence, you know what I'm saying. Yeah, it makes sense as a swarm, as a bunch of cellular cellular slime mold makes sense.
We're already familiar with the hive mind, and you know, the emergent property of a bunch of different things, you know, operating together. The real puzzler, though, is the single cell plasmodial slime mold. That's one big giant cell and the fact that it behaves in ways that seem conscious to some degree.
Yeah. So if you want to kind of go back in time to where a lot of this research research started, it wasn't actually in but it was. In the nineteen sixties, a physicist named Evelyn Fox Keller was curious if she could use math to model biological systems because they had had success using math to explain and expand our understanding of physics. So she was like, let me see if we can do this with biology. And someone said, well, you got to meet Lee Siegel. Lee Siegel is got
a little surprised for you. And Lee Siegel got together and said, oh, doctor Keller, you need to meet our friend slime mold. And doctor Keller was like, this is the nineteen sixties. I don't know what slime mold is yet. And Keller and sorry Siegel said oh, we'll just take a seat and let me tell you about this, which is dictio dictyo stell stellium, dicta stellium, right, dictyo stellium, discudium.
I think that's discoides discoidium.
Yeah, okay, but it's.
The one we were talking about earlier that creates the stems. They sacrifice themselves to create stems for the spores, right.
And I think this was just significant because it was kind of like the first time anyone had observed and you know, fell off of their lab stool and could explain it to others, these pseudo plasmodiums. But what they were missing was they were like, all right, we see this happening, and it's amazing and how are they doing this? Though? And the very first thing they thought of is like, maybe it's like an ant colony or something, and maybe there's like a leader or a pacemaker sell or maybe
a few of them. They get together and they just sort of send out chemical signals to everyone else and say go this way, and the rest are just sort of the worker ants that follow along.
Yeah, And they knew in particular that there was a chemical called cyclical amp which is related to ATP the dinocne triphosphate, and that that was how they were signaling. But they thought that like you're saying, that there are just a few signaling, everybody else was responding. And what they figured out is that that they had that totally wrong. That there weren't leaders, there weren't pacemakers who were in charge of like you know, signaling and in effect making
decisions for the group. That it was actually like a group effort, and that the the whatever whatever cell or slug that they're called in this cellular slime mold swarm was closest to food, it would signal with AMP that hey, there's some food over here, let's all go over this way, and that signal would just kind of be passed along through the swarm, through the cellular slime mold, and the slime mold would move toward the food and start eating.
Yeah, and this was you know, I mean, you can see why they went in that initial direction because it made sense. And a lot of nature is organized with a top down principle. In mind, humans often organized with a top down principle, big business, government, it's just a it's a system that we're used to seeing in in nature and in people. And so it made sense that
they went that way. And they never they never really thought about the fact that it could be like, no, it's a total bottom up system and whatever is closest can figure out send out these signals.
Yeah. So instead of like a hierarchy, it's more like like it's like how a flock of birds operate. So a flock of seagulls haircut operates where.
It runs so far away.
Yeah, but it's the hair that's closest to whatever it's running from is the first to run and everybody else follows. It's kind of like how a flock of birds will turn depending on you know, which way they need to turn based on that bird making that decision, and the rest of the flock basically following it. The bottom up,
bottom up decision making kind of thing. And so we started to learn a lot, and we know a lot about bottom up decision making now as opposed to when these guys were working back in the sixties, I think.
But in the twenty first century, that whole idea of autom up decision making or decentralized decision making has become a real component in artificial intelligence design, because if you've listened to the End of the World with Josh Clark, you know that one of the hardest things in the world to do is program something to understand everything, because you have to input all the stuff it needs to know.
Whereas if you can just kind of set up some sort of simple algorithm to let the machine think for itself, you finally got something.
Yeah, and I would imagine I didn't see this anywhere, but it seems like this might could have some applications in nanotechnology as well. Like the idea that we could program, you know, billions of tiny little nanobot bugs to clean the windows of your house every day. Nice like a lot of things collectively doing one bigger thing. Yeah, am I base there? Or could that potentially be a thing?
Not at all. I think it totally could be a thing. It's anytime you have a huge amount of things that you're trying to all get to do roughly the same thing that they need to not you know, redouble their efforts or replicate their efforts. So you don't want one cleaning one part of the window and the other one coming over and cleaning the same part of the window
that's already clean. All you have to do is figure out how to teach them if if this happens, do this, and if you can figure out how to strip it down to a basic enough algorithm that could conceivably be used for just about any situation, you've got the key to the universe in your hand, Like there's actually I read We'll have to do an episode on it one day. But I read an article but a guy who was I think he was a physicist back in the eighties who was like, I think the universe is basically an
operating system. That is, that is goes down to two. There's two bits. You could say it's black and white, one zero, it doesn't matter. But there are two kinds of bits, and depending on the combinations that these things form, everything else in the universe arises from that, including consciousness, planets, slime, mold. Everything comes out of these two types of bits that basically make up the fabric of space and time, interacting
with one another in increasingly sophisticated patterns. Wow, and that is exactly what you're talking about. So if we can figure out what that that computation is, what those algorithms are that give rise to larger and larger stuff, you can you can do anything. It's it's weird. You can do increasingly sophisticated stuff. The more basic your algorithm is. It's almost a paradox.
Yeah, this is like doctor Octagon stuff. Doctor Octagon.
I don't know, is that right from Spot? I don't Yeah he was Alchequalina.
You mean yeah, sure, all right.
I like al from Alina. I think he makes some really weird choices for parts.
He's great.
I'm sure somebody's like, hey, we'll give you ten million dollars to play doctor Octagon. I'd be like, sure, you got it. Where do I sign up?
Yeah? I need to get him a movie crush because he actually is friends of the network. He's a friend of the network. I think he's been on The Daily z eyite Geist a few times. Oh yeah, and like they booked him on some other comedy shows. I'm like, guys, throw a little Molina my way for.
Real, Molina spread all over. Movie Crush.
You've been on Daily's Eyed Guys twice. I've never half.
I've been on a movie Crush once too.
I had Miles on the Movie Crush the other day and I was given my heart time because they haven't asked me on and they think twice.
It's a hilarious keep it up, Chuck.
Yeah, he was like, uh no, man, I was like, Miles's cool.
Did he really flustered him?
I feel like he was on skates for a second there, but I let him off the hook. I'm having Jack on next week, so I'm really like going full court press here.
Yeah, Miles is like man beat beyond guard. Chuck does not punches.
It's funny because Miles, you know, as you know, is such a smart smart guy and just like having a conversation with him is always amazing. And then he comes on and he picks Maul Rats. What's his favorite movie? Was it? Really?
That's his favorite movie of all time?
Huh? I mean that's what he picked. And he was like, hey, man, I never said I had good tastes, so nice. It was pretty fun.
Do you have any hints of what Jacks is going to be?
Well, I know it's pulp fiction because he he had me save it like two years ago, and I just you know, we kept slipping through the crack. So he's gonna come on next week for pulp fiction. Very nice, all right, So let's get back to I mean, we talked about how the the d D as we're going to call it, moves around without yeah, without the pacemaker sells. But that original true slime mold, the big single celled one that's just made up of all the goopy cytoplasm.
We didn't really talk about what they do. And because if you don't have cell walls, you're like, well, how's this stuff moving around? It's actually made up of what's called oscillating units, and so these units oscillate at different frequencies. Depending what's going on, like where they are and then what their little neighbor oscillating units are doing. And so when they go close to food, they start oscillating, shaking like hey, hey, I'm near some food. And then that
just sort of gets that flow. Everyone else starts oscillating in a similar manner, and that gets that flow of cytoplasm going in that food direction.
Yeah, and so the slime mold effectively moves to the food because of that oscillating unit that looks again like a fan spreading out going to find food and then finding it, the slime mold moves toward it.
Or like you said, away from something that they don't like.
Yeah, yes, which is pretty neat. So those are the two things. It's moving toward food and moving away from something. And one of the things that they found is that slime mold can actually learn and not only learn to like stay away from something, it can actually teach other slime mold to stay away from it, even slime mold it's never been introduced to it, or alternately, it can
teach this is the really the salt garter fact. It can teach other slime mold that something that seems harmful is actually harmless?
Yeah, this is a pretty cool experiment. Yeah, so these researchers put slime molds. They built it a little tiny bridge. It was very cute, and they coated this bridge in a noxious substance. It wasn't harmful to them, it was harmless. It was like salt or something, let's say. And then they put the those little oat flakes on the other side as their ultimate temptation. And so these first slime molds start creeping up to it and sort of dipping their little toe in the water and saying, this stuff
is pretty noxious. But then they learned, right like, oh okay, so it's not actually harmful. I can go across this stuff. And what they found was that it learned to cross this little bridge just as fast as slime molds that were placed on bridges that didn't have any coating going on.
Right, So it said, okay, this stuff's fine. It's gross, is way too salty, but it's not gonna hurt me. So I'm going to get to food just as fast.
Right.
That's pretty amazing in and of self. But where it gets crazy, yes, right, they we need like a banner matter nole to come in.
And say that, yeah, totally.
So they take the slime mold and break it apart and fuse it together with other slime molds that have never been exposed to this noxious stuff before. They're called naive and the other ones are called habituated. And those naive ones when they encounter this noxious stuff like a salt bridge for the first time, they don't approach it with trepidation. They go right across it as fast as
the habituated ones that it's fused to. This is really weird because this is the first time the stuff's encountering it, and they think that somehow the habituated slime molds are passing on the information like no, no, we know it's gross,
but it's actually fine to the naive slime molds. And they figured out, chuck, that it doesn't matter if you take three habituated slime molds and fuse them with one naive slime mold, or take three naive slime molds and one just one habituated slime mold, it's going to approach us and move across it just as fast as in either situation.
Yeah, And then they also sort of figured out how long this took, so the naive slime molds. They separated after an hour of fusion with those habituated I'm gonna call them in the no molds, okay, And it forgot. It forgot that the coding was harmless, and it sort of had to approach it with a little more trepidation. But if they had been fused for three hours or more and then separated, it it remembered. I mean, it technically can't remember, but they do have this weird sort
of memory that works. And I think they even figured out some of this snail trail stuff that they leave behind acts as sort of like a spatial memory, because they come across this snail trail and say, oh, someone's already been here before.
Me, right, so there's no reason to go research this area because there clearly wasn't food there. Yeah, and again here's your ten minute reminder that slime mold don't have brains or neuron So all of this is just just astounding stuff that we're still trying to get to the bottom up, Like that habituation thing. They're like, we don't know, we have no idea, but we're going to go find out and maybe in ten years we'll be able to explain it right.
So eventually, you know, the people that are people that are hip to the slime mold thing are like.
Trying to spread though.
They're trying to spread the word to me, like this stuff is really amazing. They're doing TED talks on it. It was a really good TED talk on it, in fact, and some coders said, hey, wait a minute, you know they're doing all this amazing stuff like the overlay of the Tokyo subway and it's lining up perfectly. What if we actually generated code of the slime mold and kind of a reverse engineered it and we could see what that looked like and how we could use it.
So yeah, this one artist named Sage Jensen basically figured out or took I don't know exactly who figured out exactly what the slime mold's algorithms were, but somebody wrote them down and Sage Jensen came along and turned them into a C plus plus code and basically ran these things it's like algorithms, and found that these fractals started forming that looked essentially just like slime mold moving across a peatri edish in search of food, which is pretty
cool in and of itself. It was an art art project basically, but someone on a tea of astrophysicists heard about Sage Jensen's work and they used it when they were stumped trying to figure out how to map the invisible matter that makes up basically the structure of our universe. That if we can just crack that nut, we'll understand the universe exponentially better than we do now, but we
cannot figure out how to do it. And so, just like with the ancient roads between the Roman cities or the Tokyo subway map, someone figured out to use slime mold to basically try to try to create the structure of the universe. This invisible these invisible filaments.
Yeah, these filaments that came out of the Big Bang. So I guess they went back to Sage Jensen and said, first of all, Sage U c plus plus code. Isn't it really just be minus code? And we're being honest, And he said, that's not how it works. Get out of the mouth.
That's great coding joke.
Thank you. It's my own coding joke, and I just.
Made it the only coding joke I think.
No, I think it's not a bug. It's a feature, isn't that one? Oh that's true, true to old timy. So yeah, they went to Sage and they said, you're an artist, but this is pretty amazing. I think we
can apply it here. And they modified it. And what they did was, and of course there's always oats involved, they put a model in place with virtual slime mold cells, and they put it on a map with thirty seven thousand real galaxies and they used I guess, virtual piles of food to represent the galaxies, and the bigger the galaxy,
the bigger the pile of food. And so they did this modeling through the coating and had the virtual slime mold seek out the most efficient way to reach this, and I guess in theory they're hoping that they get a sort of map of the universe out of it.
Yeah, So when the slime mold was finished, they all stood background that that's amazing. How accurate is it? And they all just realize that they had no idea how to verify but no, surely, Like I think what they're doing is they're taking this as an initial, you know, guide, and then they'll go back and try to figure out how to verify it. And maybe the slime mold did figure out the most efficient way to link together these galaxies.
But that would be I can't even put a word on that of what that would how impressive that would be if the slime mold recreated how the universe is invisibly linked together, the structure of it.
You know, what if slime mold is God?
What if we're your sleep right now and this is all just one dream, chuck.
The other cool thing they figured out with the slime mold moving around is when they were researching them, they found that they those mazes that they were running through, they went even faster through the maze when they had some sort of noise like a bright light or something
like we said. They like to go away from things they don't like, and that negative input of that light basically made them say, all right, let's let's pick up the pace and make make these decisions quicker and get to that food.
And stop fussing around. I don't like this light staring at me.
I think we kind of blew some minds today.
I think so, my mind's definitely been blown.
Did you want to cover the Amazon thing?
Nope? Okay, good, that's it for slimld unless you got anything else, right now? Do you?
I got nothing else?
We'll have to revisit us in ten years. And thanks to Dave rus for helping us with this one. And since I said Dave Ruse, I think Chuck, it means it's time for listener mail.
Hey guys, I'm gonna call this night Trap response.
I just laugh every time I hear those words together.
Now, no night Trap. This is from Aaron. Hey, guys, just finish the Night Trap video game show. Thanks for bringing it to everyone. I own the twenty fifth anniversary edition. Like you said, it's not a good game, but has its moments. One other game worth noting is called Double Switch. It's the same style and video camera control quality, and it starred Corey Ham. Perhaps arguably a little better game,
but still had the same thing going on. Really, I'm sure your research finds lots of things that don't quite make it into the final show. Aaron, we did not know about Double Switch, so nice work there. Yeah, and Aaron says, I've listened to so many shows I feel that Chuck and I are some sort of long lost brothers separated at birth. I generally agree with just about everything he says, and I'm always fully entertained. It would be nice to meet you guys if you ever get
another tour started and make it back to Michigan. Keep up the good work of finish your book. And I have the pre order poster in my office and I've converted friends and family, So that is from Aaron and Michigan. And we're definitely gonna start touring again. I would say probably next year, although we haven't really talked much about.
It, no, but we need to. It's definitely starting to get to be time to get talking, I guess, although I admit I have not missed the traveling. I've missed being on stage, but not the traveling.
Well, you know that's what they say. That's what rockstars say.
It's not the heat, it's the humidity.
Now they say that, you know, you get paid to travel, you don't get paid to play shows.
I've never heard that before, but it really makes sense. Yeah, if you can figure out how to get paid for both, then you're really really doing something right.
Good stuff. Yeah, And if we get back to Michigan, we've already done Detroit. We've had a lot of calls over here for ann Arbor, so maybe.
That's where we go. Yes, well, who is that again, Aaron? Aaron, That's what I was gonna guess. Thanks a lot, Aaron, that was a great email. Thanks for the Corey Haym reference and all that stuff. And if you want to get in touch with us, like Aaron did, you can send us an email to Stuff Podcasts at iHeartRadio dot com.
Stuff you Should Know is a production of iHeartRadio. For more podcasts my heart Radio, visit the iHeartRadio app, Apple Podcasts, or wherever you listen to your favorite shows.