Science Friday - Harnessing the superpowers of silk
Episode Date: March 31, 2026A listener recently called in asking how they might get a pair of functioning web shooters so they could operate as a local Spider-Man. While web shooters (sadly) don’t exist, we can say that the wa...ys real spiders use silk put Peter Parker’s powers to shame. Spiders can use their sticky threads to sail through the air, capture prey larger than them, and even live underwater. And scientists trying to harness those powers. Host Flora Lichtman chats with spider-silk aficionado Cheryl Hayashi about the wonders of silk, and Fiorenzo Omenetto shares how his engineering lab uses silk in the design of biomedical tools, like vaccines and sensors. Guests: Dr. Cheryl Hayashi is the senior vice president and provost of science at the American Museum of Natural History in New York City. Dr. Fiorenzo Omenetto is a biomedical engineer and director of the Silklab at Tufts University in Massachusetts. Transcripts for each episode are available within 1-3 days at sciencefriday.com. Subscribe to this podcast. Plus, to stay updated on all things science, sign up for Science Friday's newsletters.
Transcript
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Hey, it's Flora Lichtenen, and you're listening to Science Friday.
You may have seen that the next Spider-Man movie comes out this summer.
The trailer, which came out just this month, hit a billion views.
Because I'm not just Peter Parker.
I'm Spider-Man.
And relatedly, in a superhero story, this would be called a twist of fate.
This question came in on our listener line.
My name is Christian.
I'm in Richmond, but, you know, I mean, I'm hailing from Pennsylvania, you know, the vibes.
I'm calling because I wanted to inquire about my ability to have a pair of functioning web shooters
so I can operate as a local Spider-Man, and I would love for you guys to let me know.
Okay, Christian, sci-fri to the rescue.
Although web shooters, for now are the stuff of sci-fi, the Spider-Verse did get this right.
Silk seems to have superpowers.
So what can Spider-Silk really do and how are people trying to harness it?
On the line is Spider-Silk Biologist Dr. Cheryl Hayashi,
senior vice president and provost of science at the American Museum of Natural History.
Cheryl, thanks for joining me.
Thank you.
Off the bat, give me your first reaction to Christian's question.
I love that question.
We should always be inspired by nature.
And who doesn't want to have web shooters on their body?
I agree. Is this a personal fantasy for you?
It's not to swing from buildings, but a personal fantasy for me would be if I could be a spider for a day and actually have the coordination and the ability to weave a web.
That would just be amazing.
To weave a web. That would be your fantasy. Why? Why weaving a web?
because it's one of the most remarkable wonder structures that's in nature.
In order to make a web, a spider has to be able to make the silk, and they make that silk in their body.
So in their abdomen, they have little tiny glands that pump out silk protein.
And then they have little spinnerets on their abdomens, and they touch their legs to the spinnerets,
and that's how they pull silk out.
And then they have to have sort of the right choreography in order.
to construct a web.
And that's just really hard to do.
It's just an amazing, amazing feat of engineering and design.
Yeah.
Okay.
I mean, I want to be able to picture this.
Like, in Marvel movies, you know,
the silk is shooting out of, I guess,
spinneret glands in Peter Parker's or Spider-Man's wrists.
What does it actually look like on a spider?
Each kind of soul.
So a spider has many, many silk.
And most spiders have many types of silk land and each has its own recipe, its own recipe of silk ingredients.
And so what comes out of, you know, these silk glands is a variety of different types of silk.
Some types of silk are really strong.
Some types of silk are stretchy.
Some are sticky.
Can they tune the recipe for the area of the web that they're making?
They do that in terms of they draw out a particular kind of silk for the particular architectural element of the web.
So for instance, the frame and sort of the radii, sort of the spokes, that's one kind of silk.
And a different kind of silk, a much stretchier silk would be used as the spiral that gets laid on the spokes.
And so spiders are mixing and matching the different kinds of silks they make, depending on what they need to.
do with their silk.
So it's not really spider silk.
It's spider silks.
Exactly.
There's not just one kind of spider silk.
Each spider makes at least one kind of silk.
And each type of spider silk is made up of its own, you know, set of proteins.
So that's why I always say silks.
So a lot of s is in there.
And there's over 53,000 described species of spiders.
And so if you kind of do the math, that most of them make,
more than one kind of silk, there's a lot of silk out there. A lot of spider silks to be studied.
Wow. Like in the tens of thousands, at least. Oh my gosh. Yes. Yes. Like, yes. What were you going to say?
I would add a few more zeros to that.
You know, we hear these big claims with spider silk. Like, it's stronger than steel. It's tougher than Kevlar. Is that true for some silks?
Oh, yes, it is true for some silks.
And, you know, people might say, how could that, how could that be true?
You have to think about the scale.
So spider soap is often so thin you can barely see it.
So it's very fine fibers.
And so, but they're able to do things like, you know, stop a flying insect.
Like, that takes a lot of strength and toughness.
Yeah.
Okay.
Spider-Man obviously shoots silk out.
and then uses it as a mode of transportation.
Do spiders use silk that way?
So spiders, they don't necessarily shoot silk out, like the way, you know, Spider-Man does.
Spiders tend to more pull silk out, or they might attach silk to a substrate.
Maybe it's, you know, the eve of your window or a branch, and then they might use gravity to drop from it.
So that's a common way that spider silk gets drawn out, and then they can sort of
walk on that line. Some spiders, especially tiny little spiderlings, let some soak out, and it functions
sort of like a little parachute or a little sail so they can be caught by the wind, and we call that
ballooning. So spiders can basically fly around the earth. In fact, you can even find spiders at high
altitude, little tiny spiders at high altitude, flying with their drag lines. So spiders never
evolved wings, but they can fly with their silk. That's wild. Are there any other sort of
lesser known uses of silk that we should call out? Sure. So some other lesser known uses of silk
is there's another spider called Ebola spider, which has changed their orb web down to a single line
with a single ball of sticky glue at the end.
So it's like a little ball of snot
with a little string attached to it.
And when insects approach that spider,
that spider starts swinging that bolus.
And then that little sticky ball gets stuck to the insect
and the insect goes into tethered flight
and the spider can reel it in.
I think that's a super cool use for literally being a web slinger.
A spider lasso.
I love it.
Yes, yes.
Okay, I mean, here's the thing. I don't think I'm speaking out of turn here. I don't think I'm going to say anything that's surprising. Spiders, look, are not particularly well-loved, I would say generally. And yet they do confer this great power in one of our most beloved superheroes. How do you think about our relationship with spiders?
Oh, that's a good question. Of course, I don't really relate to this thing about, you know, spiders not be.
being beloved, I find them absolutely fascinating. And so, yeah, I think that, I think it's fair,
though, that they inspire, right? I mean, they're so amazing. They've been spinning silk for
hundreds of millions of years. They're nearly everywhere on all terrestrial habitats. There's
even some spiders that live underwater. So I think they've earned their place in terms of
inspiring us. Underwater spiders? Yeah, there are.
few spiders that live underwater. Spiders never evolved gills, so they do need to have air,
so you might want to guess what they trap their air with. I'm going to guess the most amazing,
you know, material known to man, spider silk. Yeah, they basically go to the surface and air sticks
to their little hairs and their waxy body, and then they can capture the air bubble, and then they can put
into their little silk chamber.
It's like a scuba tank, a spider silk scuba tank.
Yeah, yeah.
It's just they basically, and they can hang out in there, and that's, they can go back
up to the surface and replenish, but there are some spiders that live underwater.
There's spiders that live on the shoreline, and at high tide, they'd be submerged
and at low tide, they're out.
So what they do is they live in little burrows, and they have a little door on it and make
a little waterproof door.
and you might want to guess what is that waterproof door made of?
Silk?
Yes.
Is it just amazing?
It's like better than duct tape.
Better than duct tape.
Oh, I love that.
I mean, are people trying to harness the power of Spider-Silk?
Like, is that a thing?
Oh, that's definitely a thing.
So it's been long recognized that Spider-Silk has these remarkable properties.
And so there's been a considerable effort into try to understand what's the secret?
So people study the silk proteins, they study the silk structure, and there are people that study, you know, well, how can we replicate this?
Do we replicate it by sort of, do we mimic the structure, you know, using other chemical means, or do we actually try to make a lot of silk protein?
And there's research going on in sort of all those areas.
What's the hardest part?
Is it the fabrication?
The fabrication does seem to be quite.
quite difficult. And it's just an amazing thing that, you know, when you see, you either watch a spider
make a web or you just see, you know, silk lying around your house or outdoors, that there's a
little creature that's doing something that seems so effortless for them that is really hard
for humans to do. Dr. Cheryl Hayashi, senior vice president and provost for science at the American
Museum of Natural History in New York City. Cheryl, thanks for joining me today. Thanks.
We've got to take a break, but along those lines, when we come back, we're talking to a biomedical
engineer who's trying to do just that to fabricate silk and use it for devices like sensors
and implants. Don't go away. Next, let's talk about fabrication and how exactly scientists are
putting insect silk to use. Here to pull that thread with us is Dr. Fiorenzo Omenito,
a biomedical engineer and director of the Silk Lab at Tufts University in
Massachusetts. Fia, welcome back to Science Friday. Thank you. You run a whole lab devoted to finding
silk applications. Why silk? Oh, gosh. What a tough question to answer, because from a material
standpoint, it's a very nice technical material, so it can be formed on the nanoscale. It can
interface with electronics. It can make very solid blocks. And so have all these material formats that
are very versatile. But the thing that silk really does is it's able to store and preserve the
activity of what you mix inside of it in these end formats. And an example is, for instance,
if you take this, a glass of silk and you add some blood inside of it, and then you pour it on the
table and you let it dry, once you lift up a sheet of material that looks like plastic, like a red
transparent film of plastic, and you can leave it on the table for several months,
and then cut a little piece and send it to the hospital, and then they'll take the blood out,
and your analysis, your labs from that blood are just as good as a fresh blood draw.
What?
It's like a crazy, that's an amazing preservation device.
It's the one thing that makes working with this material very exciting because you can hide superpowers in materials.
So it's really a material scientist's dream.
It gives a lot of opportunity to explore in domains that are otherwise very hard to explore.
And you use worm silk, right?
not spider silk.
We use silkworm silk, yes.
We use silk that commonly is used as a commodity material for textiles,
so there is an abundance of it,
and we deconstruct it into its liquid state
so that we can then reform it into a variety of materials.
What is it about silk?
Like, what's the secret sauce that allows it to do this,
that allows you to store?
super powers in a material.
You know, I wish I could tell you,
I could tell you that this was designed
with purpose and equations and long hours,
but I think that this is,
this is something that comes from directed evolution
of, in this case, you know,
from domesticating the silkworm over thousands of years.
And ultimately, the selection was to make
the, you know, the strongest, finest,
the most lustrous fiber that would give you,
you know, the,
the supplist scars and the best garments that you can weave.
But ultimately, this gave a molecule, a particular kind of molecule, that is very, very unusual in the
way that it assembles and in the way that it interfaces with the materials that it's mixed with.
So I think it's really nature's offering in a way, of a very technologically sophisticated,
polymer that happens to be very benign and very friendly to interface with the body or to
disperse in the environment. I mean, I feel like I always, I often see silk for for sensors,
you know, like biosensors or, you know, within the body or outside. Is that again just because
the silk can hold the actual sensing material and keep it stable in lots of different environments,
or is it playing any other role? Well, there's a little,
bit of both. I think that the main advantage of the main feature is really that silk will
stabilize chemistries that otherwise are confined to laboratories and to wet labs and to a lab
bench. And so you can imagine really that you can make silk inks that contain enzymes that
otherwise would need to be refrigerated and you can just print them on surfaces and then just
look at the way that the surfaces react to the environment around them. And so this is a very, this is a very
nice way of using the stabilization function in the bioavailability to do to do all sorts of
sensing from little adhesive patches and and you know and band-aid type reporters to printed t-shirts
that react to your body to tapestries that you hang that you hang in a room and respond to the
environment around it. I do not want my t-shirts responding to my body more than they already do.
Just saying.
Okay.
Are there silk uses in the wild that I might encounter at a store?
So the process of generating silk solution has been scaled up and has been put to industrial use in food preservation, in vaccine stabilization to give a couple of examples.
And now the production has been scaled to very large amounts.
So yes, you may encounter it.
in these domains.
You know, I love that this very ancient biomaterial
is being used in these kind of futuristic-sounding ways.
How do you think about that?
I think that it's beautiful.
I think that there's a re-contextualization
of things that used to be artisan skills
and have been around for such a long time.
But there's a beauty in reimagining things
and finding new context for materials.
that have been around for a long time.
Sometimes I talk about, they give this example of maybe there's an artisan in the world
that is just the best person at doing shoelaces and braiding the best shoelaces on the planet.
And this craft has been pushed out by industrialization and volume and scale.
But that craft becomes contemporary of the material that you use to make the shoelaces
now becomes a material that is medically relevant and can be used to replace ligament and tendons.
And so all of these things that we have around and that have all these unbelievable properties,
either from nature or from people using natural materials, have, I think, a beautiful,
a beautiful second life and maybe a third and a fourth life.
It's a lovely place to end.
Dr. Fiorenzo Omeneto is a biomedical engineer and director of the Silk Lab at Tufts University in Massachusetts.
Thanks for joining me.
Thanks for having me.
I want to thank you, Christian.
for dropping us a line.
And listeners, if you have a spidey sense about a certain question,
you think we can help with, you've surfed the web,
but haven't found an answer that sticks,
give us a ring.
We love hearing what you're interested in,
and we love looking into your questions.
8774.
Sifry, 8774 SciFri.
Just leave us voicemail.
This episode was produced by Rasha Auretti.
I'm Flora Lichten.
We'll catch you next time.