Your brain on improv | Charles Limb | TEDxMidAtlantic

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0:05 - 0:07

Thank you, it's a pleasure to be here.
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So I am a surgeon who studies creativity,
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and I have never had a patient tell me,
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"I really want you
to be creative during surgery,"
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and so I guess
there's a little bit of irony to it.
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I will say though that,
after having done surgery a lot,
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it's similar to playing
a musical instrument.
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And for me, this deep
and enduring fascination with sound
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is what led me to both be a surgeon
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and to study the science
of sound, particularly music.
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I'm going to talk
over the next few minutes
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about my career
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in terms of how I'm able to study music
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and try to grapple
with all these questions
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of how the brain is able to be creative.
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I've done most of this work
at Johns Hopkins University,
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and at the National Institute
of Health where I was previously.
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I'll go over some science experiments
and cover three musical experiments.
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I will start off by playing
a video for you.
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This video is of Keith Jarrett,
who's a well-known jazz improviser
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and probably the most
well-known, iconic example
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of someone who takes improvisation
to a higher level.
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And he'll improvise entire concerts
off the top of his head,
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and he'll never play it
exactly the same way again,
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so as a form of intense creativity,
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I think this is a great example.
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And so why don't we go
and click the video.
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(Music)
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(Music ends)
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It's really a remarkable
thing that happens there.
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I've always as a listener, as a fan,
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I listen to that, and I'm astounded.
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I think -- how can this possibly be?
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How can the brain generate
that much information,
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that much music, spontaneously?
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And so I set out
with this concept, scientifically,
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that artistic creativity,
it's magical, but it's not magic,
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meaning that it's a product of the brain.
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There's not too many brain-dead
people creating art.
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With this notion that artistic creativity
is in fact a neurologic product,
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I took this thesis that we could study it
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just like we study any other
complex neurologic process,
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and there are subquestions
that I put there.
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Is it possible to study
creativity scientifically?
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And I think that's a good question.
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And I'll tell you that most
scientific studies of music,
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they're very dense,
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and when you go through them,
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it's very hard to recognize
the music in it.
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In fact, they seem to be
unmusical entirely
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and to miss the point of the music.
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This brings the second question:
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Why should scientists study creativity?
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Maybe we're not the right people to do it.
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(Laughter)
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Well it may be, but I will say that,
from a scientific perspective,
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we talked a lot about innovation today,
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the science of innovation,
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how much we understand
about how the brain is able to innovate
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is in its infancy,
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and truly, we know very little
about how we are able to be creative.
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I think that we're going to see,
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over the next 10, 20, 30 years,
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a real science of creativity
that's burgeoning
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and is going to flourish,
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Because we now have new methods
that can enable us
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to take this process
like complex jazz improvisation,
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and study it rigorously.
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So it gets down to the brain.
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All of us have this remarkable brain,
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which is poorly understood,
to say the least.
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I think that neuroscientists
have more questions than answers,
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and I'm not going
to give you answers today,
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just ask a lot of questions.
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And that's what I do in my lab.
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I ask questions about what is the brain
doing to enable us to do this.
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This is the main method that I use.
This is functional MRI.
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If you've been in an MRI scanner,
it's very much the same,
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but this one is outfitted in a special way
to not just take pictures of your brain,
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but to also take pictures
of active areas of the brain.
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The way that's done is by the following:
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There's something called BOLD imaging,
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which is Blood Oxygen
Level Dependent imaging.
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When you're in an fMRI scanner,
you're in a big magnet
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that's aligning your molecules
in certain areas.
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When an area of the brain is active,
meaning a neural area is active,
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it gets blood flow shunted to that area.
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That blood flow causes an increase
in local blood to that area
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with a deoxyhemoglobin
change in concentration.
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Deoxyhemoglobin can be detected by MRI,
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whereas oxyhemoglobin can't.
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So through this method of inference --
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and we're measuring blood flow,
not neural activity --
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we say that an area of the brain
that's getting more blood
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was active during a particular task,
and that's the crux of how fMRI works.
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And it's been used since the '90s
to study really complex processes.
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I'm going to review a study that I did,
which was jazz in an fMRI scanner.
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It was done with a colleague,
Alan Braun, at the NIH.
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This is a short video
of how we did this project.
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(Video) Charles Limb: This is a plastic
MIDI piano keyboard
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that we use for the jazz experiments.
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And it's a 35-key keyboard
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designed to fit both inside the scanner,
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be magnetically safe,
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have minimal interference
that would contribute to any artifact,
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and have this cushion
so that it can rest on the players' legs
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while they're lying down in the scanner,
playing on their back.
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It works like this --
this doesn't actually produce any sound.
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It sends out what's called
a MIDI signal --
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or a Musical Instrument
Digital Interface --
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through these wires into the box
and then the computer,
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which then trigger
high-quality piano samples like this.
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(Music)
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Now I'm going to demo it for you.
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I'm using two mirrors to see my fingers.
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(Music)
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This is improvized.
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(Music ends)
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OK, so it works.
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And so through this piano keyboard,
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we have the means to take
a musical process and study it.
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So what do you do now that you have
this cool piano keyboard?
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You can't just say,
"It's great we have a keyboard."
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We have to come up
with a scientific experiment.
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The experiment
really rests on the following:
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What happens in the brain during something
that's memorized and over-learned,
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and what happens in the brain
during something
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that is spontaneously
generated, or improvised,
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in a way that's matched motorically
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and in terms of lower-level
sensory motor features?
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I have here what we call the paradigms.
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There's a scale paradigm, which is playing
a scale up and down, memorized,
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then there's improvising on a scale,
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quarter notes, metronome, right hand --
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scientifically very safe,
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but musically really boring.
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Then there's the bottom one,
which is called the jazz paradigm.
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So we brought professional
jazz players to the NIH,
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and we had them memorize
this piece of music on the lower-left,
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which is what you heard me playing --
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and we had them improvise
to the same chord changes.
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And if you can hit
that lower-right sound icon,
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that's an example
of what was recorded in the scanner.
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(Music)
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(Music ends)
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In the end, it's not the most
natural environment,
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but they're able to play real music.
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And I've listened to that solo 200 times,
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and I still like it.
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And the musicians
were comfortable in the end.
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We first measured the number of notes.
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Were they playing more notes
when they were improvising?
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That was not what was going on.
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And then we looked at the brain activity.
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I will try to condense this for you.
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These are contrast maps that are showing
subtractions between what changes
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when you're improvising
vs. when you're doing something memorized.
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In red is an area that's active
in the prefrontal cortex,
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the frontal lobe of the brain,
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and in blue is this area
that was deactivated.
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So we had this focal area
called the medial prefrontal cortex
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that went way up in activity.
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We had this broad patch of area
called the lateral prefrontal cortex
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that went way down in activity,
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I'll summarize that for you.
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These are multifunctional
areas of the brain,
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these are not the jazz areas of the brain.
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They do a whole host of things
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that have to do with self-reflection,
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introspection, working memory etc.
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Really, consciousness is seated
in the frontal lobe.
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But we have this combination
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of an area that's thought to be involved
in self-monitoring, turning off,
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and this area that's thought
to be autobiographical,
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or self-expressive, turning on.
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We think, at least in this preliminary --
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it's one study; it's probably wrong,
but it's one study --
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(Laughter)
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we think that at least
a reasonable hypothesis
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is that, to be creative,
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you should have this weird dissociation
in your frontal lobe.
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One area turns on,
and a big area shuts off,
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so that you're not inhibited,
you're willing to make mistakes,
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so that you're not constantly
shutting down
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all of these new generative impulses.
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Now a lot of people know that music
is not always a solo activity --
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sometimes it's done communicatively.
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The next question was:
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What happens when musicians
are trading back and forth,
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something called "trading fours,"
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which is something they do
normally in a jazz experiment.
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So this is a 12-bar blues,
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and I've broken it
down into four-bar groups,
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so you would know how you would trade.
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We brought a musician
into the scanner, same way,
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had them memorize this melody
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then had another musician
out in the control room
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trading back and forth interactively.
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This is another video
I'll show you of this.
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(Music)
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So this is a musician, Mike Pope,
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one of the world's best bassists
and a fantastic piano player.
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(Music)
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He's now playing the piece
that we just saw
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a little better than I wrote it.
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(Video) CL: Mike, come on in.
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Mike Pope: May the force be with you.
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Nurse: Nothing in your pockets, Mike?
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MP: No. Nothing's in my pockets.
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CL: You have to have the right
attitude to agree to do it.
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(Laughter)
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It's kind of fun, actually.
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(Music)
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Now we're playing back and forth.
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He's in there.
You can see his legs up there.
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(Music)
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And then I'm in the control room here,
playing back and forth.
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(Music)
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(Music ends)
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(Video) Mike Pope:
This is a pretty good representation
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of what it's like.
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And it's good that it's not too quick.
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The fact that we do it over and over again
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lets you acclimate to your surroundings.
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So the hardest thing for me
was the kinesthetic thing,
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looking at my hands through two mirrors,
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laying on my back,
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and not able to move at all
except for my hand.
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That was challenging.
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But again --
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there were moments, for sure --
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(Laughter)
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there were moments of real, honest-to-God
musical interplay, for sure.
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CL: At this point,
I'll take a few moments.
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So what you're seeing here --
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and I'm doing a cardinal sin in science,
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which is to show you preliminary data.
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This is one subject's data.
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This is, in fact, Mike Pope's data.
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So what am I showing you here?
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When he was trading fours with me,
improvising vs. memorized,
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his language areas lit up,
his Broca's area,
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in the inferior frontal gyrus on the left.
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He had it also homologous on the right.
12:13 - 12:17

This is an area thought to be
involved in expressive communication.
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This whole notion
that music is a language --
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maybe there's a neurologic
basis to it after all,
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and we can see it when two musicians
are having a musical conversation.
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So we've done this on eight subjects now,
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and we're getting all the data together,
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hopefully we'll have something
to say about it meaningfully.
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Now when I think about improvisation
and the language, what's next?
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Rap, of course, rap -- freestyle.
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I've always been fascinated by freestyle.
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And let's play this video.
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(Video) Mos Def: Brown skin I be,
standing five-ten I be
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Rockin' it when I be, in your vicinity
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Whole-style synergy, recognize symmetry
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Go and try to injure me,
broke 'em down chemically
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Ain't the number 10 MC,
talk about how been I be
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Styled it like Kennedy,
late like a 10 to three
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When I say when I be,
girls say bend that key cut
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CL: So there's a lot of analogy
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between what takes place
in freestyle rap and jazz.
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There are a lot of correlates
between the two forms of music,
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I think, in different time periods,
in lot of ways,
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rap serves the same social function
that jazz used to serve.
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So how do you study rap scientifically?
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And my colleagues think I'm crazy,
but I think it's very viable.
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This is what you do:
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You have a freestyle artist come
and memorize a rap
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that you write for them,
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that they've never heard before,
and then you have them freestyle.
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So I told my lab members
that I would rap for TED,
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and they said, "No, you won't."
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And then I thought --
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(Laughter)
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(Applause)
13:38 - 13:40

But here's the thing.
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With this big screen,
you can all rap with me. OK?
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So what we had them do
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was memorize this lower-left
sound icon, please.
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This is the control condition.
This is what they memorized.
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Computer: Memory, thump.
13:52 - 13:54

CL: Thump of the beat in a known repeat
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Rhythm and rhyme, they make me complete
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The climb is sublime when I'm on the mic
13:59 - 14:02

Spittin' rhymes that hit you
like a lightning strike
14:02 - 14:03

Computer: Search.
14:03 - 14:05

CL: I search for the truth
in this eternal quest
14:05 - 14:08

My passion's not fashion,
you can see how I'm dressed
14:08 - 14:10

Psychopathic words in my head appear
14:10 - 14:12

Whisper these lyrics only I can hear
14:12 - 14:13

Computer: Art.
14:13 - 14:16

CL: The art of discovering
and that which is hovering
14:16 - 14:18

Inside the mind of those unconfined
14:18 - 14:21

All of these words keep
pouring out like rain
14:21 - 14:24

I need a mad scientist to check my brain
14:24 - 14:25

Computer: Stop.
14:25 - 14:32

(Applause)
14:34 - 14:36

I guarantee you
that will never happen again.
14:36 - 14:38

(Laughter)
14:38 - 14:41

So now, what's great
about these free-stylers,
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they will get cued different words.
14:43 - 14:44

They don't know what's coming,
14:44 - 14:46

but they'll hear something off the cuff.
14:46 - 14:47

Go hit that right sound icon,
14:47 - 14:50

there will be cued three square words:
like, not and head.
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He doesn't know what's coming.
Computer: Like.
14:52 - 14:54

Freestyler: I'm like some kind of
14:54 - 14:56

extraterrestrial, celestial scene
14:56 - 14:59

Back in the days, I used to sit
in pyramids and meditate
14:59 - 15:01

With two microphones -- Computer: Head
15:01 - 15:03

hovering over my head
15:03 - 15:04

See if I could still listen,
15:04 - 15:05

spittin' off the sound
15:05 - 15:07

See what you grinning
15:07 - 15:09

I teach the children
in the back of the classroom
15:09 - 15:12

About the message of apocalyptical
15:12 - 15:13

Computer: Not.
15:13 - 15:15

Not really though,
'cause I've got to keep it simple
15:15 - 15:17

instrumental
15:17 - 15:20

Detrimental playing Super Mario
15:20 - 15:23

boxes [unclear] hip hop
15:23 - 15:25

Computer: Stop.
15:25 - 15:27

CL: It's an incredible
thing that's taking place.
15:27 - 15:29

It's doing something
neurologically remarkable.
15:29 - 15:32

Whether or not you like
the music is irrelevant.
15:32 - 15:34

Creatively speaking,
it's just a phenomenal thing.
15:34 - 15:36

This is a short video
of how we do this in a scanner.
15:37 - 15:38

[fMRI of Hip-Hop Rap]
15:38 - 15:39

(Laughter)
15:39 - 15:41

(Video) CL: We're here with Emmanuel.
15:41 - 15:43

CL: That was recorded
in the scanner, by the way.
15:43 - 15:45

(Video) CL: That's Emmanuel
in the scanner.
15:46 - 15:48

He's just memorized a rhyme for us.
15:49 - 15:52

[Control Condition Memorized Verses]
15:52 - 15:54

Emmanuel: Top of the beat with no repeat
15:54 - 15:57

Rhythm and rhyme make me complete
15:58 - 16:00

Climb is sublime when I'm on the mic
16:00 - 16:03

Spittin' rhymes that'll hit you
like a lightning strike
16:03 - 16:04

Computer: Search.
16:04 - 16:07

I search for the truth
in this eternal quest
16:07 - 16:09

I'm passing on fashion;
you can see how I'm dressed
16:09 - 16:12

CL: I'm going to stop that there;
so what do we see in his brain?
16:12 - 16:14

This is four rappers' brains.
16:14 - 16:16

And we do see language areas lighting up,
16:16 - 16:17

but then, eyes closed --
16:18 - 16:21

when you are freestyling vs. memorizing,
16:21 - 16:23

you've got major visual areas lighting up.
16:23 - 16:27

You've got major cerebellar activity,
which is involved in motor coordination.
16:27 - 16:30

You have heightened brain activity
when you're doing a comparable task,
16:30 - 16:33

when that one task is creative
and the other task is memorized.
16:33 - 16:36

It's very preliminary,
but I think it's kind of cool.
16:36 - 16:38

To conclude, we've got
a lot of questions to ask,
16:38 - 16:41

and like I said, we'll ask questions
here, not answer them.
16:41 - 16:45

But we want to get at the root
of what is creative genius neurologically,
16:45 - 16:47

and I think, with these methods,
we're getting close.
16:47 - 16:50

And I think, hopefully
in the next 10, 20 years,
16:50 - 16:51

you'll see real, meaningful studies
16:51 - 16:54

that say science has to catch up to art,
16:54 - 16:57

and maybe we're starting now to get there.
16:57 - 16:59

Thank you for your time.
16:59 - 17:03

(Applause)

Title:: Your brain on improv | Charles Limb | TEDxMidAtlantic
Description:: Musician and researcher Charles Limb wondered how the brain works during musical improvisation -- so he put jazz musicians and rappers in an fMRI to find out. What he and his team found has deep implications for our understanding of creativity of all kinds.

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Video Language:: English
Team:: closed TED
Project:: TEDxTalks
Duration:: 17:14

	TED Translators admin edited English subtitles for TEDxMidAtlantic 2010 - Charles Limb - 11/5/10
	TED Translators admin edited English subtitles for TEDxMidAtlantic 2010 - Charles Limb - 11/5/10

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Your brain on improv | Charles Limb | TEDxMidAtlantic

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