How to pronounce "stoked"

Transcriber: Joseph Geni Reviewer: Madeleine Aronson

Today I want to tell you

about a project being carried out

by scientists all over the world

to paint a neural portrait of the human mind.

And the central idea of this work

is that the human mind and brain

is not a single, general-purpose processor,

but a collection of highly specialized components,

each solving a different specific problem,

and yet collectively making up

who we are as human beings and thinkers.

To give you a feel for this idea,

imagine the following scenario:

You walk into your child's day care center.

As usual, there's a dozen kids there

waiting to get picked up,

but this time,

the children's faces look weirdly similar,

and you can't figure out which child is yours.

Do you need new glasses?

Are you losing your mind?

You run through a quick mental checklist.

No, you seem to be thinking clearly,

and your vision is perfectly sharp.

And everything looks normal

except the children's faces.

You can see the faces,

but they don't look distinctive,

and none of them looks familiar,

and it's only by spotting an orange hair ribbon

that you find your daughter.

This sudden loss of the ability to recognize faces

actually happens to people.

It's called prosopagnosia,

and it results from damage

to a particular part of the brain.

The striking thing about it

is that only face recognition is impaired;

everything else is just fine.

Prosopagnosia is one of many surprisingly specific

mental deficits that can happen after brain damage.

These syndromes collectively

have suggested for a long time

that the mind is divvied up into distinct components,

but the effort to discover those components

has jumped to warp speed

with the invention of brain imaging technology,

especially MRI.

So MRI enables you to see internal anatomy

at high resolution,

so I'm going to show you in a second

a set of MRI cross-sectional images

through a familiar object,

and we're going to fly through them

and you're going to try to figure out what the object is.

Here we go.

It's not that easy. It's an artichoke.

Okay, let's try another one,

starting from the bottom and going through the top.

Broccoli! It's a head of broccoli.

Isn't it beautiful? I love that.

Okay, here's another one. It's a brain, of course.

In fact, it's my brain.

We're going through slices through my head like that.

That's my nose over on the right, and now

we're going over here, right there.

So this picture's nice, if I do say so myself,

but it shows only anatomy.

The really cool advance with functional imaging

happened when scientists figured out how to make

pictures that show not just anatomy but activity,

that is, where neurons are firing.

So here's how this works.

Brains are like muscles.

When they get active,

they need increased blood flow to supply that activity,

and lucky for us, blood flow control to the brain is local,

so if a bunch of neurons, say, right there

get active and start firing,

then blood flow increases just right there.

So functional MRI picks up on that blood flow increase,

producing a higher MRI response

where neural activity goes up.

So to give you a concrete feel

for how a functional MRI experiment goes

and what you can learn from it

and what you can't,

let me describe one of the first studies I ever did.

We wanted to know if there was a special part of the brain for recognizing faces,

and there was already reason to think there might be such a thing

based on this phenomenon of prosopagnosia

that I described a moment ago,

but nobody had ever seen that part of the brain

in a normal person,

so we set out to look for it.

So I was the first subject.

I went into the scanner, I lay on my back,

I held my head as still as I could

while staring at pictures of faces like these

and objects like these

and faces and objects for hours.

So as somebody who has pretty close to the world record

of total number of hours spent inside an MRI scanner,

I can tell you that one of the skills

that's really important for MRI research

is bladder control.

(Laughter)

When I got out of the scanner,

I did a quick analysis of the data,

looking for any parts of my brain

that produced a higher response when I was looking at faces

than when I was looking at objects,

and here's what I saw.

Now this image looks just awful by today's standards,

but at the time I thought it was beautiful.

What it shows is that region right there,

that little blob,

it's about the size of an olive

and it's on the bottom surface of my brain

about an inch straight in from right there.

And what that part of my brain is doing

is producing a higher MRI response,

that is, higher neural activity,

when I was looking at faces

than when I was looking at objects.

So that's pretty cool,

but how do we know this isn't a fluke?

Well, the easiest way

is to just do the experiment again.

So I got back in the scanner,

I looked at more faces and I looked at more objects

and I got a similar blob,

and then I did it again

and I did it again

and again and again,

and around about then

I decided to believe it was for real.

But still, maybe this is something weird about my brain

and no one else has one of these things in there,

so to find out, we scanned a bunch of other people

and found that pretty much everyone

has that little face-processing region

in a similar neighborhood of the brain.

So the next question was,

what does this thing really do?

Is it really specialized just for face recognition?

Well, maybe not, right?

Maybe it responds not only to faces

but to any body part.

Maybe it responds to anything human

or anything alive

or anything round.

The only way to be really sure that that region

is specialized for face recognition

is to rule out all of those hypotheses.

So we spent much of the next couple of years

scanning subjects while they looked at lots

of different kinds of images,

and we showed that that part of the brain

responds strongly when you look at

any images that are faces of any kind,

and it responds much less strongly

to any image you show that isn't a face,

like some of these.

So have we finally nailed the case

that this region is necessary for face recognition?

No, we haven't.

Brain imaging can never tell you

if a region is necessary for anything.

All you can do with brain imaging

is watch regions turn on and off

as people think different thoughts.

To tell if a part of the brain is necessary for a mental function,

you need to mess with it and see what happens,

and normally we don't get to do that.

But an amazing opportunity came about

very recently when a couple of colleagues of mine

tested this man who has epilepsy

and who is shown here in his hospital bed

where he's just had electrodes placed

on the surface of his brain

to identify the source of his seizures.

So it turned out by total chance

that two of the electrodes

happened to be right on top of his face area.

So with the patient's consent,

the doctors asked him what happened

when they electrically stimulated that part of his brain.

Now, the patient doesn't know

where those electrodes are,

and he's never heard of the face area.

So let's watch what happens.

It's going to start with a control condition

that will say "Sham" nearly invisibly

in red in the lower left,

when no current is delivered,

and you'll hear the neurologist speaking to the patient first. So let's watch.

(Video) Neurologist: Okay, just look at my face

and tell me what happens when I do this.

All right?

Patient: Okay.

Neurologist: One, two, three.

Patient: Nothing. Neurologist: Nothing? Okay.

I'm going to do it one more time.

Look at my face.

One, two, three.

Patient: You just turned into somebody else.

Your face metamorphosed.

Your nose got saggy, it went to the left.

You almost looked like somebody I'd seen before,

but somebody different.

That was a trip.

(Laughter)

Nancy Kanwisher: So this experiment —

(Applause) —

this experiment finally nails the case

that this region of the brain is not only

selectively responsive to faces

but causally involved in face perception.

So I went through all of these details

about the face region to show you what it takes

to really establish that a part of the brain

is selectively involved in a specific mental process.

Next, I'll go through much more quickly

some of the other specialized regions of the brain

that we and others have found.

So to do this, I've spent a lot of time

in the scanner over the last month

so I can show you these things in my brain.

So let's get started. Here's my right hemisphere.

So we're oriented like that. You're looking at my head this way.

Imagine taking the skull off

and looking at the surface of the brain like that.

Okay, now as you can see,

the surface of the brain is all folded up.

So that's not good. Stuff could be hidden in there.

We want to see the whole thing,

so let's inflate it so we can see the whole thing.

Next, let's find that face area I've been talking about

that responds to images like these.

To see that, let's turn the brain around

and look on the inside surface on the bottom,

and there it is, that's my face area.

Just to the right of that is another region

that is shown in purple

that responds when you process color information,

and near those regions are other regions

that are involved in perceiving places,

like right now, I'm seeing this layout of space around me

and these regions in green right there

are really active.

There's another one out on the outside surface again

where there's a couple more face regions as well.

Also in this vicinity

is a region that's selectively involved

in processing visual motion,

like these moving dots here,

and that's in yellow at the bottom of the brain,

and near that is a region that responds

when you look at images of bodies and body parts

like these, and that region is shown in lime green

at the bottom of the brain.

Now all these regions I've shown you so far

are involved in specific aspects of visual perception.

Do we also have specialized brain regions

for other senses, like hearing?

Yes, we do. So if we turn the brain around a little bit,

here's a region in dark blue

that we reported just a couple of months ago,

and this region responds strongly

when you hear sounds with pitch, like these.

(Sirens)

(Cello music)

(Doorbell)

In contrast, that same region does not respond strongly

when you hear perfectly familiar sounds

that don't have a clear pitch, like these.

(Chomping)

(Drum roll)

(Toilet flushing)

Okay. Next to the pitch region

is another set of regions that are selectively responsive

when you hear the sounds of speech.

Okay, now let's look at these same regions.

In my left hemisphere, there's a similar arrangement —

not identical, but similar —

and most of the same regions are in here,

albeit sometimes different in size.

Now, everything I've shown you so far

are regions that are involved in different aspects of perception,

vision and hearing.

Do we also have specialized brain regions

for really fancy, complicated mental processes?

Yes, we do.

So here in pink are my language regions.

So it's been known for a very long time

that that general vicinity of the brain

is involved in processing language,

but we showed very recently

that these pink regions

respond extremely selectively.

They respond when you understand the meaning of a sentence,

but not when you do other complex mental things,

like mental arithmetic

or holding information in memory

or appreciating the complex structure

in a piece of music.

The most amazing region that's been found yet

is this one right here in turquoise.

This region responds

when you think about what another person is thinking.

So that may seem crazy,

but actually, we humans do this all the time.

You're doing this when you realize

that your partner is going to be worried

if you don't call home to say you're running late.

I'm doing this with that region of my brain right now

when I realize that you guys

are probably now wondering about

all that gray, uncharted territory in the brain,

and what's up with that?

Well, I'm wondering about that too,

and we're running a bunch of experiments in my lab right now

to try to find a number of other

possible specializations in the brain

for other very specific mental functions.

But importantly, I don't think we have

specializations in the brain

for every important mental function,

even mental functions that may be critical for survival.

In fact, a few years ago,

there was a scientist in my lab

who became quite convinced

that he'd found a brain region

for detecting food,

and it responded really strongly in the scanner

when people looked at images like this.

And further, he found a similar response

in more or less the same location

in 10 out of 12 subjects.

So he was pretty stoked,

and he was running around the lab

telling everyone that he was going to go on "Oprah"

with his big discovery.

But then he devised the critical test:

He showed subjects images of food like this

and compared them to images with very similar

color and shape, but that weren't food, like these.

And his region responded the same

to both sets of images.

So it wasn't a food area,

it was just a region that liked colors and shapes.

So much for "Oprah."

But then the question, of course, is,

how do we process all this other stuff

that we don't have specialized brain regions for?

Well, I think the answer is that in addition

to these highly specialized components that I've been describing,

we also have a lot of very general- purpose machinery in our heads

that enables us to tackle

whatever problem comes along.

In fact, we've shown recently that

these regions here in white

respond whenever you do any difficult mental task

at all —

well, of the seven that we've tested.

So each of the brain regions that I've described

to you today

is present in approximately the same location

in every normal subject.

I could take any of you,

pop you in the scanner,

and find each of those regions in your brain,

and it would look a lot like my brain,

although the regions would be slightly different

in their exact location and in their size.

What's important to me about this work

is not the particular locations of these brain regions,

but the simple fact that we have

selective, specific components of mind and brain

in the first place.

I mean, it could have been otherwise.

The brain could have been a single,

general-purpose processor,

more like a kitchen knife

than a Swiss Army knife.

Instead, what brain imaging has delivered

is this rich and interesting picture of the human mind.

So we have this picture of very general-purpose

machinery in our heads

in addition to this surprising array

of very specialized components.

It's early days in this enterprise.

We've painted only the first brushstrokes

in our neural portrait of the human mind.

The most fundamental questions remain unanswered.

So for example, what does each of these regions do exactly?

Why do we need three face areas

and three place areas,

and what's the division of labor between them?

Second, how are all these things

connected in the brain?

With diffusion imaging,

you can trace bundles of neurons

that connect to different parts of the brain,

and with this method shown here,

you can trace the connections of individual neurons in the brain,

potentially someday giving us a wiring diagram

of the entire human brain.

Third, how does all of this

very systematic structure get built,

both over development in childhood

and over the evolution of our species?

To address questions like that,

scientists are now scanning

other species of animals,

and they're also scanning human infants.

Many people justify the high cost of neuroscience research

by pointing out that it may help us someday

to treat brain disorders like Alzheimer's and autism.

That's a hugely important goal,

and I'd be thrilled if any of my work contributed to it,

but fixing things that are broken in the world

is not the only thing that's worth doing.

The effort to understand the human mind and brain

is worthwhile even if it never led to the treatment

of a single disease.

What could be more thrilling

than to understand the fundamental mechanisms

that underlie human experience,

to understand, in essence, who we are?

This is, I think, the greatest scientific quest

of all time.

(Applause)