-
♪ (guitar music) ♪
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(Peter) These days,
you hear music all the time.
-
It wakes us up, motivates our workouts,
-
keeps us company on our commutes.
-
It doesn't matter
what kind of music it is,
-
music itself has the ability
to affect our moods and our bodies
-
in all sorts of ways.
-
We nod our heads, we sway, dance.
-
Music can give us chills,
-
even make us cry.
-
Music activates every area
of the brain that we have so far mapped.
-
There's no area of the brain we know about
-
that music doesn't touch in some way.
-
But what's behind all that?
-
What exactly does music do to us?
-
To find out, I went
to a whole series of tests
-
designed to measure my responses to music.
-
I met some kids whose brains
may actually be changing,
-
thanks to those hours
of learning, practice, and performing.
-
I spoke with a therapist who used music
-
to help former congresswoman
Gabrielle Giffords
-
learn to speak again,
-
and got a glimpse inside the brain
-
of a two-time Grammy-winning artist
-
while he played...
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♪ (playing and singing) ♪
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...all to find out how music affects us.
-
♪ (upbeat music) ♪
-
So what's going on
when we listen to music?
-
We visited the USC Brain
and Creativity Institute,
-
where I had my head examined, literally,
-
to try to figure it out.
-
I'm going to go into this fMRI machine.
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A tiny tube will surround me.
-
We'll get a baseline reading of my brain.
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Then I'm going to listen to some music,
-
and we're going to see
how my brain responds.
-
Just close your eyes, relax,
-
and try and get into the music
as best you can, okay?
-
♪ (classical music) ♪
-
(Peter) And here's what we saw.
-
These are scans of my brain.
-
The areas in red are where
my activity is above average;
-
in blue, below average.
-
As you can see,
there's red activity all over my brain,
-
not just in one specific area.
-
(Daniel) Twenty-five years ago,
-
the idea was that language
is on the left side of the brain
-
and music is in
the right side of the brain.
-
But now that we've got
better quality tools,
-
higher resolution neuroimaging,
and better experimental methods,
-
we've discovered that's not at all right.
-
How does that play out
in different regions of the brain?
-
When music enters
and then gets shuttled off
-
to different parts of the brain,
-
it stops at specialized processing units
in auditory cortex.
-
They track loudness and pitch and rhythm
-
and timbre and things like that.
-
There's visual cortex activation
when you're reading music as a musician
-
or watching music.
-
Motor cortex
when you're tapping your feet,
-
snapping your fingers,
clapping your hands.
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And cerebellum which mediates
the emotional responses.
-
The memory system and the hippocampus,
-
hearing a familiar passage,
-
finding it somewhere in your memory banks.
-
Music is going on
in both halves of your brain,
-
the left and the right,
the front and the back,
-
the inside and the outside.
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♪ (singing) ♪
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(Peter) So what about a musician's brain?
-
To play a piece of music
engages so many things:
-
motor systems, timing systems,
-
memory systems, hearing systems.
-
There's all sorts
of brain activity happening.
-
It's a very robust thing to play music.
-
♪ (Chopin, "Fantaisie-Impromptu") ♪
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I'm Alex Jacob Robertson.
-
I'm Nathan Glenn Robertson.
-
(Peter) We asked
these 11-year old musicians
-
to tell us what's going through
their minds when they play.
-
Some of the most important things
are, I think, good postures,
-
getting the note right,
-
legato, staccato.
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♪ (violin) ♪
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For the violin, you need to hold
your hand at the right place,
-
and you need to be in tune,
-
and then you also have to have
not only the right intonation
-
but the right sound,
-
and then you also need
to have great vibrato.
-
There's lot of things to think about.
-
(Peter) Back at USC,
-
researchers have been studying kids
who play music over the past five years
-
to see how it affects their development.
-
The multi-tasking areas of their brains
understandably lit up,
-
but they've seen other results, too.
-
Music training
over the course of five years
-
has had benefits in cognitive skills
and decision making,
-
also had some benefits in social behavior,
-
and we've also seen changes
in the associated brain structures.
-
(Peter) Did you hear that?
Changes in brain structures!
-
They found that the brains of children
who have studied music
-
have stronger connections
between the left and right hemispheres,
-
and that can make them better,
more creative problem-solvers.
-
And then there's emotion.
-
♪ (violin) ♪
-
When you hear a piece like this...
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♪ (Saint-Saëns, "Le Cygne") ♪
-
...it's easy to understand why emotions
play such a big part in music.
-
This song by Camille Saint-Saëns
-
is known as the music
for The Dying Swan in ballet.
-
While it might move ballerinas to dance,
-
it inspires different reactions in others.
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♪ (violin continues) ♪
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Some people get goosebumps, chills.
-
That weird tingly sensation that you get
-
when a great piece of music
just hits you in the right way?
-
It's called frisson,
and not everyone gets it.
-
But it turns out I do.
-
Now we're going to have you listen
to some pieces of music.
-
When you experience a chill, if you do,
-
I want you to just press this space bar
so we have an indication
-
of when those peak moments
of enjoyment are happening.
-
(Peter) Matt Sachs,
a PhD candidate at USC,
-
wired me up to measure
my physiological response.
-
So when I'm feeling
that emotional connection
-
that has a physical manifestation,
-
we'll see what my body is actually doing?
-
Exactly.
-
♪ (Saint-Saëns, "Le Cygne") ♪
-
Alright, how was that?
-
That was-- That had a lot of them.
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We got them all.
-
(Peter) Now full disclosure:
back in the day, I played the cello,
-
which might have something to do
with why that particular song affected me.
-
Nice hair!
-
But it turns out the brain
is at work here too.
-
We processed the difference
between this pathway
-
that connects the auditory regions,
which is on the side of the brain here,
-
to the emotional regions,
-
and we showed that the tract
actually that connects those two regions
-
is stronger.
-
There's more fibers in that region
in people who get chills.
-
(Peter) Which means
that some people's brains
-
might have better communication
between what they hear and how they feel.
-
The music itself also plays
a role in frisson.
-
Sachs uses different songs in his lectures
to see if students get it.
-
I'll say, "Raise your hand
when you get a chill,"
-
and I play a piece of music,
a classical piece,
-
and maybe half the people will get it.
-
(Peter) But then he plays this...
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♪ (The Rolling Stones, "Gimme Shelter") ♪
-
Rolling Stone's Gimme Shelter.
-
Have you ever seen the movie
20 Feet from Stardom?
-
- The documentary about backup singers?
- Yeah.
-
There's a part where they isolate
the vocals from Gimme Shelter.
-
♪ (backup vocals) ♪
-
And I play that,
-
and 90% of the people experience chills,
-
sort of independent of where I go.
-
I have to tell you, bringing that up
made me think about it
-
and I got that little kind of thing
at the back of my neck.
-
(Peter) But why would that happen?
-
The high pitched notes that she hit
almost sounds like a scream
-
and it's very important ancestrally for us
-
to be able to pay attention to a scream,
-
figure out what's going on,
-
and either run or fight,
whatever we need to do.
-
(Peter) So how come
that manifests as pleasure?
-
Well it's because our pre-frontal cortex,
-
the more rational, thinking part
of the brain kicks in.
-
So you realize very quickly,
-
after you have
this really quick startle reflex,
-
that there's nothing actually threatening
about the piece of music,
-
that you're sitting in a safe space
with your headphones on,
-
and it's in that reappraisal
-
that we tend to think
of the pleasure responses emerging.
-
And whether you find listening to music
so pleasurable you get chills
-
or you absolutely despise a song,
-
it can produce absolutely
fascinating effects in the brain.
-
According to [Levitan], music we enjoy
-
triggers the brain's
internal opioid system--
-
yes, opioid system.
-
And just like the opioids
that come in pill form
-
these chemicals make you feel good
and help relieve pain.
-
And music you don't like?
Well, that releases cortisol,
-
the notorious stress hormone.
-
But that's not even the half of what music
can do in the brain.
-
Can you turn on the lights?
-
(Peter) When former Congresswomen
Gabrielle Giffords
-
was shot in 2011
-
the left side of her brain
was severely damaged,
-
leaving her struggling to speak,
-
a condition called aphasia.
-
Gabby, are you frustrated?
-
(Peter) But to get an idea
-
of just how powerful
music's effect on the brain can be,
-
watch this video.
-
You ready?
-
(together) This little light of mine
I'm gonna let it shine.
-
(Peter) That word that she'd been
struggling to say, "light,"
-
came easily in song.
-
Why would she be able to sing a word
when she's unable to say it?
-
What we know about the brain
-
is that the left hemisphere
controls language,
-
and there are many
other parts of the brain
-
that have music access.
-
Music therapist Maegan Morrow's job
-
is to help patients use
those other pathways to regain language.
-
Sometimes I compare it
to being in traffic,
-
and you can't move any further,
-
but you might need to exit
and take the feeder road
-
to get you to your destination.
-
So music is basically
like that feeder road
-
to the new destination.
-
(Peter) Like a detour.
-
So we know that music
can help us relearn things like speech
-
by accessing alternative
pathways in the brain
-
and that learning to play music
can help strengthen brain connections.
-
But what about making music?
-
To make music is like--
-
it's the language of humanity.
-
No matter where I go in the world,
-
if I'm playing something,
-
it doesn't matter if someone
can't speak the language--
-
if they're into it, they're into it.
-
(Peter) This is Xavier Dphrepaulezz,
better known as Fantastic Negrito.
-
We brought him to UCSF
to meet Charles Limb,
-
a neuroscientist
who studies musical creativity.
-
The Duffler's up next.
-
(Peter) To understand
how Fantastic Negrito's brain works
-
when making music,
-
Dr. Limb had him play on of his songs
while going through the fMRI.
-
(Fantastic Negrito singing)
-
(Peter) So how did his brain respond?
-
The areas that process sensory
and motor skills, along with sounds,
-
lit up.
-
You can see them here in red and yellow.
-
Makes sense, right?
-
But here's the really interesting part.
-
Limb asked him to improvise
-
to see what happens when he's creating
something totally original.
-
(Fantastic Negrito singing)
-
Now watch what happens to his brain?
-
Stop!
-
(laughter)
-
Now watch what happens to his brain.
-
The areas that were active before,
-
the ones that deal
with motor skills and sounds,
-
are even more active.
-
But see how there's way more blue
in the front of his brain?
-
That's the pre-frontal cortex,
-
and it's associated
with effortful planning
-
and conscience self-monitoring,
-
and it's blue because it's less active.
-
We see that the pre-frontal cortex
-
appears to be really shutting down
in these moments of high creativity,
-
kind of like letting of of these conscious
self-censoring or self-monitoring areas
-
that normally are there
to help control our output.
-
(Peter) And Limb says
it's about more than just letting go.
-
You view it
from a perspective of survival.
-
If human beings only could do
memorized route responses,
-
we'd be long gone.
-
It is not just the thing that happens
in clubs and in jazz bars,
-
it's actually maybe
the most fundamental form
-
of what it means to be human,
-
to come up with new ideas.
-
(singing)
-
(Peter) So music is so much more
than notes on a page.
-
It can change the way we think
and speak and feel.
-
But is there a limit
to what science can tell us about music?
-
Just when I discovered
the answer to one thing,
-
five new questions pop up
that are more interesting than the first,
-
and I've gained an appreciation
-
for how complex the music-making
and music-listening system is.
-
It's not demystified for me at all.
-
It's more mysterious than ever.
-
(singing)
-
(applause)
Amplifying Voices
