How to pronounce "spongy"

Translator: Timothy Covell Reviewer: Morton Bast

When I go to parties,

it doesn't usually take very long

for people to find out

that I'm a scientist and I study sex.

And then I get asked questions.

And the questions usually have a very particular format.

They start with the phrase,

"A friend told me,"

and then they end with the phrase,

"Is this true?"

And most of the time

I'm glad to say that I can answer them,

but sometimes I have to say,

"I'm really sorry,

but I don't know

because I'm not that kind of a doctor."

That is, I'm not a clinician,

I'm a comparative biologist who studies anatomy.

And my job is to look at lots of different species of animals

and try to figure out how their tissues and organs work

when everything's going right,

rather than trying to figure out

how to fix things when they go wrong,

like so many of you.

And what I do is I look for similarities and differences

in the solutions that they've evolved

for fundamental biological problems.

So today I'm here to argue

that this is not at all

an esoteric Ivory Tower activity

that we find at our universities,

but that broad study

across species, tissue types and organ systems

can produce insights

that have direct implications for human health.

And this is true both of my recent project

on sex differences in the brain,

and my more mature work

on the anatomy and function of penises.

And now you know why I'm fun at parties.

(Laughter)

So today I'm going to give you an example

drawn from my penis study

to show you how knowledge

drawn from studies of one organ system

provided insights into a very different one.

Now I'm sure as everyone in the audience already knows --

I did have to explain it to my nine-year-old late last week --

penises are structures that transfer sperm

from one individual to another.

And the slide behind me

barely scratches the surface

of how widespread they are in animals.

There's an enormous amount of anatomical variation.

You find muscular tubes, modified legs, modified fins,

as well as the mammalian fleshy, inflatable cylinder

that we're all familiar with --

or at least half of you are.

(Laughter)

And I think we see this tremendous variation

because it's a really effective solution

to a very basic biological problem,

and that is getting sperm in a position

to meet up with eggs and form zygotes.

Now the penis isn't actually required for internal fertiliztion,

but when internal fertilization evolves,

penises often follow.

And the question I get when I start talking about this most often is,

"What made you interested in this subject?"

And the answer is skeletons.

You wouldn't think that skeletons and penises

have very much to do with one another.

And that's because we tend to think of skeletons

as stiff lever systems

that produce speed or power.

And my first forays into biological research,

doing dinosaur paleontology as an undergraduate,

were really squarely in that realm.

But when I went to graduate school to study biomechanics,

I really wanted to find a dissertation project

that would expand our knowledge of skeletal function.

I tried a bunch of different stuff.

A lot of it didn't pan out.

But then one day I started thinking

about the mammalian penis.

And it's really an odd sort of structure.

Before it can be used for internal fertilization,

its mechanical behavior has to change

in a really dramatic fashion.

Most of the time it's a flexible organ.

It's easy to bend.

But before it's brought into use

during copulation

it has to become rigid,

it has to become difficult to bend.

And moreover, it has to work.

A reproductive system that fails to function

produces an individual that has no offspring,

and that individual is then kicked out of the gene pool.

And so I thought, "Here's a problem

that just cries out for a skeletal system --

not one like this one,

but one like this one --

because, functionally,

a skeleton is any system

that supports tissue and transmits forces.

And I already knew that animals like this earthworm,

indeed most animals,

don't support their tissues

by draping them over bones.

Instead they're more like reinforced water balloons.

They use a skeleton that we call a hydrostatic skeleton.

And a hydrostatic skeleton

uses two elements.

The skeletal support comes from an interaction

between a pressurized fluid

and a surrounding wall of tissue

that's held in tension and reinforced with fibrous proteins.

And the interaction is crucial.

Without both elements you have no support.

If you have fluid

with no wall to surround it

and keep pressure up,

you have a puddle.

And if you have just the wall

with no fluid inside of it to put the wall in tension,

you've got a little wet rag.

When you look at a penis in cross section,

it has a lot of the hallmarks

of a hydrostatic skeleton.

It has a central space

of spongy erectile tissue

that fills with fluid -- in this case blood --

surrounded by a wall of tissue

that's rich in a stiff structural protein called collagen.

But at the time when I started this project,

the best explanation I could find for penal erection

was that the wall surrounded these spongy tissues,

and the spongy tissues filled with blood

and pressure rose and voila! it became erect.

And that explained to me expansion --

made sense: more fluid, you get tissues that expand --

but it didn't actually explain erection.

Because there was no mechanism in this explanation

for making this structure hard to bend.

And no one had systematically looked at the wall tissue.

So I thought, wall tissue's important in skeletons.

It has to be part of the explanation.

And this was the point

at which my graduate adviser said,

"Whoa! Hold on. Slow down."

Because after about six months of me talking about this,

I think he finally figured out

that I was really serious about the penis thing.

(Laughter)

So he sat me down, and he warned me.

He was like, "Be careful going down this path.

I'm not sure this project's going to pan out."

Because he was afraid I was walking into a trap.

I was taking on a socially embarrassing question

with an answer that he thought

might not be particularly interesting.

And that was because

every hydrostatic skeleton

that we had found in nature up to that point

had the same basic elements.

It had the central fluid,

it had the surrounding wall,

and the reinforcing fibers in the wall

were arranged in crossed helices

around the long axis of the skeleton.

So the image behind me

shows a piece of tissue

in one of these cross helical skeletons

cut so that you're looking at the surface of the wall.

The arrow shows you the long axis.

And you can see two layers of fibers,

one in blue and one in yellow,

arranged in left-handed and right-handed angles.

And if you weren't just looking at a little section of the fibers,

those fibers would be going in helices

around the long axis of the skeleton --

something like a Chinese finger trap,

where you stick your fingers in and they get stuck.

And these skeletons have a particular set of behaviors,

which I'm going to demonstrate in a film.

It's a model skeleton

that I made out of a piece of cloth

that I wrapped around an inflated balloon.

The cloth's cut on the bias.

So you can see that the fibers wrap in helices,

and those fibers can reorient as the skeleton moves,

which means the skeleton's flexible.

It lengthens, shortens and bends really easily

in response to internal or external forces.

Now my adviser's concern

was what if the penile wall tissue

is just the same as any other hydrostatic skeleton.

What are you going to contribute?

What new thing are you contributing

to our knowledge of biology?

And I thought, "Yeah, he does have a really good point here."

So I spent a long, long time thinking about it.

And one thing kept bothering me,

and that's, when they're functioning,

penises don't wiggle.

(Laughter)

So something interesting had to be going on.

So I went ahead, collected wall tissue,

prepared it so it was erect,

sectioned it, put it on slides

and then stuck it under the microscope to have a look,

fully expecting to see crossed helices of collagen of some variety.

But instead I saw this.

There's an outer layer and an inner layer.

The arrow shows you the long axis of the skeleton.

I was really surprised at this.

Everyone I showed it

was really surprised at this.

Why was everyone surprised at this?

That's because we knew theoretically

that there was another way

of arranging fibers in a hydrostatic skeleton,

and that was with fibers at zero degrees

and 90 degrees to the long axis of the structure.

The thing is, no one had ever seen it before in nature.

And now I was looking at one.

Those fibers in that particular orientation

give the skeleton a very, very different behavior.

I'm going to show a model

made out of exactly the same materials.

So it'll be made of the same cotton cloth,

same balloon, same internal pressure.

But the only difference

is that the fibers are arranged differently.

And you'll see that, unlike the cross helical model,

this model resists extension and contraction

and resists bending.

Now what that tells us

is that wall tissues are doing so much more

than just covering the vascular tissues.

They're an integral part of the penile skeleton.

If the wall around the erectile tissue wasn't there,

if it wasn't reinforced in this way,

the shape would change,

but the inflated penis would not resist bending,

and erection simply wouldn't work.

It's an observation with obvious medical applications

in humans as well,

but it's also relevant in a broad sense, I think,

to the design of prosthetics, soft robots,

basically anything

where changes of shape and stiffness are important.

So to sum up:

Twenty years ago,

I had a college adviser tell me,

when I went to the college and said,

"I'm kind of interested in anatomy,"

they said, "Anatomy's a dead science."

He couldn't have been more wrong.

I really believe that we still have a lot to learn

about the normal structure and function of our bodies.

Not just about its genetics and molecular biology,

but up here in the meat end of the scale.

We've got limits on our time.

We often focus on one disease,

one model, one problem,

but my experience suggests

that we should take the time

to apply ideas broadly between systems

and just see where it takes us.

After all, if ideas about invertebrate skeletons

can give us insights

about mammalian reproductive systems,

there could be lots of other wild and productive connections

lurking out there just waiting to be found.

Thank you.

(Applause)