GUEST
BLOG—By Vilayanur Ramachadran, TED 2007--I study
the human brain, the functions and structure of the human brain. And I just
want you to think for a minute about what this entails. Here is this mass of
jelly, three-pound mass of jelly you can hold in the palm of your hand, and it
can contemplate the vastness of interstellar space. It can contemplate the
meaning of infinity and it can contemplate itself contemplating on the meaning
of infinity. And this peculiar recursive quality that we call self-awareness,
which I think is the holy grail of neuroscience, of neurology, and hopefully,
someday, we'll understand how that happens.
ABOUT
THE AUTHOR
V.S. Ramachadran is the director
of the Center for Brain and Cognition at the University of California, San
Diego, and an adjunct professor at the Salk Institute. He is the author of Phantoms in the Brain
(the basis for a Nova special), A Brief Tour of Human Consciousness and The Man
with the Phantom Twin: Adventures in the Neuroscience of the Human Brain.
OK, so how do you study this mysterious organ? I mean, you have 100 billion nerve cells, little wisps of protoplasm, interacting with each other, and from this activity emerges the whole spectrum of abilities that we call human nature and human consciousness. How does this happen? Well, there are many ways of approaching the functions of the human brain. One approach, the one we use mainly, is to look at patients with sustained damage to a small region of the brain, where there's been a genetic change in a small region of the brain. What then happens is not an across-the-board reduction in all your mental capacities, a sort of blunting of your cognitive ability. What you get is a highly selective loss of one function, with other functions being preserved intact, and this gives you some confidence in asserting that that part of the brain is somehow involved in mediating that function. So you can then map function onto structure, and then find out what the circuitry's doing to generate that particular function. So that's what we're trying to do.
So let me give you a few striking examples of this. In fact,
I'm giving you three examples, six minutes each, during this talk. The first
example is an extraordinary syndrome called Capgras syndrome. If you look at
the first slide there, that's the temporal lobes, frontal lobes, parietal
lobes, OK -- the lobes that constitute the brain. And if you look, tucked away
inside the inner surface of the temporal lobes -- you can't see it there -- is
a little structure called the fusiform gyrus. And that's been called the face
area in the brain, because when it's damaged, you can no longer recognize
people's faces. You can still recognize them from their voice and say, "Oh
yeah, that's Joe," but you can't look at their face and know who it is,
right? You can't even recognize yourself in the mirror. I mean, you know it's
you because you wink and it winks, and you know it's a mirror, but you don't
really recognize yourself as yourself.
OK. Now that syndrome is well known as caused by damage to
the fusiform gyrus. But there's another rare syndrome, so rare, in fact, that
very few physicians have heard about it, not even neurologists. This is called
the Capgras delusion, and that is a patient, who's otherwise completely normal,
has had a head injury, comes out of coma, otherwise completely normal, he looks
at his mother and says, "This looks exactly like my mother, this woman,
but she's an impostor. She's some other woman pretending to be my mother."
Now, why does this happen? Why would somebody -- and this person is perfectly
lucid and intelligent in all other respects, but when he sees his mother, his
delusion kicks in and says, it's not mother.
Now, the most common interpretation of this, which you find
in all the psychiatry textbooks, is a Freudian view, and that is that this chap
-- and the same argument applies to women, by the way, but I'll just talk about
guys. When you're a little baby, a young baby, you had a strong sexual
attraction to your mother. This is the so-called Oedipus complex of Freud. I'm
not saying I believe this, but this is the standard Freudian view. And then, as
you grow up, the cortex develops, and inhibits these latent sexual urges
towards your mother. Thank God, or you would all be sexually aroused when you
saw your mother. And then what happens is, there's a blow to your head,
damaging the cortex, allowing these latent sexual urges to emerge, flaming to
the surface, and suddenly and inexplicably you find yourself being sexually
aroused by your mother. And you say, "My God, if this is my mom, how come
I'm being sexually turned on? She's some other woman. She's an impostor."
It's the only interpretation that makes sense to your damaged brain.
This has never made much sense to me, this argument. It's very
ingenious, as all Freudian arguments are but didn't make much sense because I
have seen the same delusion, a patient having the same delusion, about his pet
poodle. He'll say, "Doctor, this is not Fifi. It looks exactly like Fifi,
but it's some other dog." Right? Now, you try using the Freudian
explanation there. You'll start talking about the latent bestiality in all
humans, or some such thing, which is quite absurd, of course.
Now, what's really going on? So, to explain this curious
disorder, we look at the structure and functions of the normal visual pathways
in the brain. Normally, visual signals come in, into the eyeballs, go to the
visual areas in the brain. There are, in fact, 30 areas in the back of your
brain concerned with just vision, and after processing all that, the message
goes to a small structure called the fusiform gyrus, where you perceive faces.
There are neurons there that are sensitive to faces. You can call it the face
area of the brain, right? I talked about that earlier. Now, when that area's
damaged, you lose the ability to see faces, right?
But from that area, the message cascades into a structure
called the amygdala in the limbic system, the emotional core of the brain, and
that structure, called the amygdala, gauges the emotional significance of what
you're looking at. Is it prey? Is it predator? Is it mate? Or is it something
absolutely trivial, like a piece of lint, or a piece of chalk, or a -- I don't
want to point to that, but -- or a shoe, or something like that? OK? Which you
can completely ignore. So if the amygdala is excited, and this is something
important, the messages then cascade into the autonomic nervous system. Your
heart starts beating faster. You start sweating to dissipate the heat that
you're going to create from muscular exertion. And that's fortunate, because we
can put two electrodes on your palm and measure the change in skin resistance
produced by sweating. So I can determine, when you're looking at something,
whether you're excited or whether you're aroused, or not, OK? And I'll get to
that in a minute.
So my idea was, when this chap looks at an object, when he
looks at his -- any object for that matter, it goes to the visual areas and,
however, and it's processed in the fusiform gyrus, and you recognize it as a
pea plant, or a table, or your mother, for that matter, OK? And then the
message cascades into the amygdala, and then goes down the autonomic nervous
system. But maybe, in this chap, that wire that goes from the amygdala to the
limbic system, the emotional core of the brain, is cut by the accident. So because
the fusiform is intact, the chap can still recognize his mother, and says,
"Oh yeah, this looks like my mother." But because the wire is cut to
the emotional centers, he says, "But how come, if it's my mother, I don't
experience a warmth?" Or terror, as the case may be? Right? (Laughter) And
therefore, he says, "How do I account for this inexplicable lack of
emotions? This can't be my mother. It's some strange woman pretending to be my
mother."
How do you test this? Well, what you do is, if you take any
one of you here, and put you in front of a screen, and measure your galvanic
skin response, and show pictures on the screen, I can measure how you sweat
when you see an object, like a table or an umbrella. Of course, you don't
sweat. If I show you a picture of a lion, or a tiger, or a pinup, you start
sweating, right? And, believe it or not, if I show you a picture of your mother
-- I'm talking about normal people -- you start sweating. You don't even have
to be Jewish.
Now, what happens if you show this patient? You take the
patient and show him pictures on the screen and measure his galvanic skin
response. Tables and chairs and lint, nothing happens, as in normal people, but
when you show him a picture of his mother, the galvanic skin response is flat.
There's no emotional reaction to his mother, because that wire going from the
visual areas to the emotional centers is cut. So his vision is normal because
the visual areas are normal, his emotions are normal -- he'll laugh, he'll cry,
so on and so forth -- but the wire from vision to emotions is cut and therefore
he has this delusion that his mother is an impostor. It's a lovely example of
the sort of thing we do: take a bizarre, seemingly incomprehensible, neural
psychiatric syndrome and say that the standard Freudian view is wrong, that, in
fact, you can come up with a precise explanation in terms of the known neural
anatomy of the brain.
By the way, if this patient then goes, and mother phones
from an adjacent room -- phones him -- and he picks up the phone, and he says,
"Wow, mom, how are you? Where are you?" There's no delusion through
the phone. Then, she approaches him after an hour, he says, "Who are you?
You look just like my mother." OK? The reason is there's a separate pathway
going from the hearing centers in the brain to the emotional centers, and
that's not been cut by the accident. So this explains why through the phone he
recognizes his mother, no problem. When he sees her in person, he says it's an
impostor.
OK, how is all this complex circuitry set up in the brain?
Is it nature, genes, or is it nurture? And we approach this problem by
considering another curious syndrome called phantom limb. And you all know what
a phantom limb is. When an arm is amputated, or a leg is amputated, for
gangrene, or you lose it in war -- for example, in the Iraq war, it's now a
serious problem -- you continue to vividly feel the presence of that missing
arm, and that's called a phantom arm or a phantom leg. In fact, you can get a
phantom with almost any part of the body. Believe it or not, even with internal
viscera. I've had patients with the uterus removed -- hysterectomy -- who have
a phantom uterus, including phantom menstrual cramps at the appropriate time of
the month. And in fact, one student asked me the other day, "Do they get
phantom PMS?" (Laughter) A subject ripe for scientific enquiry, but we
haven't pursued that.
OK, now the next question is, what can you learn about
phantom limbs by doing experiments? One of the things we've found was, about
half the patients with phantom limbs claim that they can move the phantom.
It'll pat his brother on the shoulder, it'll answer the phone when it rings,
it'll wave goodbye. These are very compelling, vivid sensations. The patient's
not delusional. He knows that the arm is not there, but, nevertheless, it's a
compelling sensory experience for the patient. But however, about half the
patients, this doesn't happen. The phantom limb -- they'll say, "But
doctor, the phantom limb is paralyzed. It's fixed in a clenched spasm and it's
excruciatingly painful. If only I could move it, maybe the pain will be
relieved."
Now, why would a phantom limb be paralyzed? It sounds like
an oxymoron. But when we were looking at the case sheets, what we found was,
these people with the paralyzed phantom limbs, the original arm was paralyzed
because of the peripheral nerve injury. The actual nerve supplying the arm was
severed, was cut, by say, a motorcycle accident. So the patient had an actual
arm, which is painful, in a sling for a few months or a year, and then, in a
misguided attempt to get rid of the pain in the arm, the surgeon amputates the
arm, and then you get a phantom arm with the same pains, right? And this is a
serious clinical problem. Patients become depressed. Some of them are driven to
suicide, OK?
So, how do you treat this syndrome? Now, why do you get a
paralyzed phantom limb? When I looked at the case sheet, I found that they had
an actual arm, and the nerves supplying the arm had been cut, and the actual
arm had been paralyzed, and lying in a sling for several months before the
amputation, and this pain then gets carried over into the phantom itself.
Why does this happen? When the arm was intact, but
paralyzed, the brain sends commands to the arm, the front of the brain, saying,
"Move," but it's getting visual feedback saying, "No."
Move. No. Move. No. Move. No. And this gets wired into the circuitry of the
brain, and we call this learned paralysis, OK? The brain learns, because of
this Hebbian, associative link, that the mere command to move the arm creates a
sensation of a paralyzed arm. And then, when you've amputated the arm, this
learned paralysis carries over into your body image and into your phantom, OK?
Now, how do you help these patients? How do you unlearn the
learned paralysis, so you can relieve him of this excruciating, clenching spasm
of the phantom arm? Well, we said, what if you now send the command to the
phantom, but give him visual feedback that it's obeying his command, right?
Maybe you can relieve the phantom pain, the phantom cramp. How do you do that?
Well, virtual reality. But that costs millions of dollars. So, I hit on a way
of doing this for three dollars, but don't tell my funding agencies.
OK? What you do is you create what I call a mirror box. You
have a cardboard box with a mirror in the middle, and then you put the phantom
-- so my first patient, Derek, came in. He had his arm amputated 10 years ago.
He had a brachial avulsion, so the nerves were cut and the arm was paralyzed,
lying in a sling for a year, and then the arm was amputated. He had a phantom
arm, excruciatingly painful, and he couldn't move it. It was a paralyzed
phantom arm.
So he came there, and I gave him a mirror like that, in a
box, which I call a mirror box, right? And the patient puts his phantom left
arm, which is clenched and in spasm, on the left side of the mirror, and the
normal hand on the right side of the mirror, and makes the same posture, the
clenched posture, and looks inside the mirror. And what does he experience? He
looks at the phantom being resurrected, because he's looking at the reflection
of the normal arm in the mirror, and it looks like this phantom has been
resurrected. "Now," I said, "now, look, wiggle your phantom --
your real fingers, or move your real fingers while looking in the mirror."
He's going to get the visual impression that the phantom is moving, right?
That's obvious, but the astonishing thing is, the patient then says, "Oh
my God, my phantom is moving again, and the pain, the clenching spasm, is
relieved."
And remember, my first patient who came in? My first patient
came in, and he looked in the mirror, and I said, "Look at your reflection
of your phantom." And he started giggling, he says, "I can see my
phantom." But he's not stupid. He knows it's not real. He knows it's a
mirror reflection, but it's a vivid sensory experience. Now, I said, "Move
your normal hand and phantom." He said, "Oh, I can't move my phantom.
You know that. It's painful." I said, "Move your normal hand."
And he says, "Oh my God, my phantom is moving again. I don't believe this!
And my pain is being relieved." OK? And then I said, "Close your
eyes." He closes his eyes. "And move your normal hand."
"Oh, nothing. It's clenched again." "OK, open your eyes."
"Oh my God, oh my God, it's moving again!" So, he was like a kid in a
candy store.
So, I said, OK, this proves my theory about learned
paralysis and the critical role of visual input, but I'm not going to get a
Nobel Prize for getting somebody to move his phantom limb. (Laughter)
(Applause) It's a completely useless ability, if you think about it. (Laughter)
But then I started realizing, maybe other kinds of paralysis that you see in
neurology, like stroke, focal dystonias -- there may be a learned component to
this, which you can overcome with the simple device of using a mirror.
So, I said, "Look, Derek" -- well, first of all,
the guy can't just go around carrying a mirror to alleviate his pain -- I said,
"Look, Derek, take it home and practice with it for a week or two. Maybe,
after a period of practice, you can dispense with the mirror, unlearn the
paralysis, and start moving your paralyzed arm, and then, relieve yourself of
pain." So he said OK, and he took it home. I said, "Look, it's, after
all, two dollars. Take it home."
So, he took it home, and after two weeks, he phones me, and
he said, "Doctor, you're not going to believe this." I said,
"What?" He said, "It's gone." I said, "What's
gone?" I thought maybe the mirror box was gone. (Laughter) He said,
"No, no, no, you know this phantom I've had for the last 10 years? It's
disappeared." And I said -- I got worried, I said, my God, I mean I've
changed this guy's body image, what about human subjects, ethics and all of
that? And I said, "Derek, does this bother you?" He said, "No,
last three days, I've not had a phantom arm and therefore no phantom elbow
pain, no clenching, no phantom forearm pain, all those pains are gone away. But
the problem is I still have my phantom fingers dangling from the shoulder, and
your box doesn't reach." (Laughter) "So, can you change the design
and put it on my forehead, so I can, you know, do this and eliminate my phantom
fingers?" He thought I was some kind of magician.
Now, why does this happen? It's because the brain is faced
with tremendous sensory conflict. It's getting messages from vision saying the
phantom is back. On the other hand, there's no appropriate reception, muscle
signals saying that there is no arm, right? And your motor command saying there
is an arm, and, because of this conflict, the brain says, to hell with it,
there is no phantom, there is no arm, right? It goes into a sort of denial --
negates the signals. And when the arm disappears, the bonus is, the pain
disappears because you can't have disembodied pain floating out there, in
space. So, that's the bonus.
Now, this technique has been tried on dozens of patients by
other groups in Helsinki, so it may prove to be valuable as a treatment for
phantom pain, and indeed, people have tried it for stroke rehabilitation.
Stroke you normally think of as damage to the fibers, nothing you can do about
it. But, it turns out some component of stroke paralysis is also learned
paralysis, and maybe that component can be overcome using mirrors. This has
also gone through clinical trials, helping lots and lots of patients.
OK, let me switch gears now to the third part of my talk,
which is about another curious phenomenon called synesthesia. This was
discovered by Francis Galton in the nineteenth century. He was a cousin of
Charles Darwin. He pointed out that certain people in the population, who are
otherwise completely normal, had the following peculiarity: every time they see
a number, it's colored. Five is blue, seven is yellow, eight is chartreuse,
nine is indigo, OK? Bear in mind, these people are completely normal in other
respects. Or C sharp -- sometimes, tones evoke color. C sharp is blue, F sharp
is green, another tone might be yellow, right?
Why does this happen? This is called synesthesia. Galton
called it synesthesia, a mingling of the senses. In us, all the senses are
distinct. These people muddle up their senses. Why does this happen? One of the
two aspects of this problem are very intriguing. Synesthesia runs in families,
so Galton said this is a hereditary basis, a genetic basis. Secondly,
synesthesia is about -- and this is what gets me to my point about the main theme
of this lecture, which is about creativity -- synesthesia is eight times more
common among artists, poets, novelists and other creative people than in the
general population. Why would that be? I'm going to answer that question. It's
never been answered before.
OK, what is synesthesia? What causes it? Well, there are
many theories. One theory is they're just crazy. Now, that's not really a
scientific theory, so we can forget about it. Another theory is they are acid
junkies and potheads, right? Now, there may be some truth to this, because it's
much more common here in the Bay Area than in San Diego. OK. Now, the third
theory is that -- well, let's ask ourselves what's really going on in
synesthesia. All right?
So, we found that the color area and the number area are
right next to each other in the brain, in the fusiform gyrus. So we said,
there's some accidental cross wiring between color and numbers in the brain.
So, every time you see a number, you see a corresponding color, and that's why
you get synesthesia. Now remember -- why does this happen? Why would there be
crossed wires in some people? Remember I said it runs in families? That gives
you the clue. And that is, there is an abnormal gene, a mutation in the gene
that causes this abnormal cross wiring.
In all of us, it turns out we are born with everything wired
to everything else. So, every brain region is wired to every other region, and
these are trimmed down to create the characteristic modular architecture of the
adult brain. So, if there's a gene causing this trimming and if that gene
mutates, then you get deficient trimming between adjacent brain areas. And if
it's between number and color, you get number-color synesthesia. If it's
between tone and color, you get tone-color synesthesia. So far, so good.
Now, what if this gene is expressed everywhere in the brain,
so everything is cross-connected? Well, think about what artists, novelists and
poets have in common, the ability to engage in metaphorical thinking, linking
seemingly unrelated ideas, such as, "It is the east, and Juliet is the
Sun." Well, you don't say, Juliet is the sun, does that mean she's a
glowing ball of fire? I mean, schizophrenics do that, but it's a different
story, right? Normal people say, she's warm like the sun, she's radiant like
the sun, she's nurturing like the sun. Instantly, you've found the links.
Now, if you assume that this greater cross wiring and
concepts are also in different parts of the brain, then it's going to create a
greater propensity towards metaphorical thinking and creativity in people with
synesthesia. And, hence, the eight times more common incidence of synesthesia
among poets, artists and novelists. OK, it's a very phrenological view of
synesthesia. The last demonstration -- can I take one minute? (Applause)
OK. I'm going to show you that you're all synesthetes, but
you're in denial about it. Here's what I call Martian alphabet. Just like your
alphabet, A is A, B is B, C is C. Different shapes for different phonemes,
right? Here, you've got Martian alphabet. One of them is Kiki, one of them is
Buba. Which one is Kiki and which one is Buba? How many of you think that's
Kiki and that's Buba? Raise your hands. Well, it's one or two mutants. How many
of you think that's Buba, that's Kiki? Raise your hands. Ninety-nine percent of
you.
Now, none of you is a Martian. How did you do that? It's
because you're all doing a cross-model synesthetic abstraction, meaning you're
saying that that sharp inflection -- ki-ki, in your auditory cortex, the hair
cells being excited -- Kiki, mimics the visual inflection, sudden inflection of
that jagged shape. Now, this is very important, because what it's telling you
is your brain is engaging in a primitive -- it's just -- it looks like a silly
illusion, but these photons in your eye are doing this shape, and hair cells in
your ear are exciting the auditory pattern, but the brain is able to extract
the common denominator. It's a primitive form of abstraction, and we now know
this happens in the fusiform gyrus of the brain, because when that's damaged,
these people lose the ability to engage in Buba Kiki, but they also lose the
ability to engage in metaphor.
If you ask this guy, what -- "all that glitters is not
gold," what does that mean?" The patient says, "Well, if it's
metallic and shiny, it doesn't mean it's gold. You have to measure its specific
gravity, OK?" So, they completely miss the metaphorical meaning. So, this
area is about eight times the size in higher -- especially in humans -- as in
lower primates. Something very interesting is going on here in the angular
gyrus, because it's the crossroads between hearing, vision and touch, and it
became enormous in humans. And something very interesting is going on. And I
think it's a basis of many uniquely human abilities like abstraction, metaphor
and creativity. All of these questions that philosophers have been studying for
millennia, we scientists can begin to explore by doing brain imaging, and by
studying patients and asking the right questions. Thank you.
SOURCE: TED.com
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