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Imagine, for a second,
a duck teaching a french class,
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a ping-pong match in orbit
around a black hole,
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a dolphin balancing a pineapple.
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You probably haven't actually seen
any of these things,
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but you could imagine them instantly.
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How does your brain produce an image
of something you've never seen?
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That may not seem hard,
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but that's only because
we're so used to doing it.
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It turns out that this is actually
a complex problem
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that requires sophisticated coordination
inside your brain.
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That's because to create
these new, weird images,
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your brain takes familiar pieces
and assembles them in new ways,
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like a collage made
from fragments of photos.
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The brain has to juggle a sea of thousands
of electrical signals
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getting them all to their destination
at precisely the right time.
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When you look at an object,
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thousands of neurons
in your posterior cortex fire.
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These neurons encode various
characteristics of the object -
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spiky, fruit, brown, green, and yellow.
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This synchronous firing strengthens the
connections between that set of neurons,
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linking them together into what's known
as a neuronal ensemble,
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in this case the one for pineapple.
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In neuroscience, this is called
the Hebbian principle,
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neurons that fire together wire together.
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If you try to imagine a pineapple later,
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the whole ensemble will light up,
assembling a complete mental image.
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Dolphins are encoded by a different
neuronal ensemble.
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In fact, every object that you've seen
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is encoded by a neuronal ensemble
associated with it,
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the neurons wired together
by that synchronized firing.
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But this principle doesn't explain
the infinite number of objects
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that we can conjure up in our imaginations
without ever seeing them.
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The neuronal ensemble for a dolphin
balancing a pineapple doesn't exist.
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So how come you can imagine it anyway?
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One hypothesis,
called the Mental Synthesis Theory,
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says that, again, timing is key.
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If the neuronal ensembles
for the dolphin and pineapple
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are activated at the same time,
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we can perceive the two separate objects
as a single image.
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But something in your brain
has to coordinate that firing.
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One plausible candidate
is the prefrontal cortex,
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which is involved in
all complex cognitive functions.
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Prefrontal cortex neurons are connected
to the posterior cortex
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by long, spindly cell extensions
called neural fibers.
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The mental synthesis theory proposes
that like a puppeteer pulling the strings,
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the prefrontal cortex neurons send
electrical signals
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down these neural fibers
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to multiple ensembles
in the posterior cortex.
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This activates them in unison.
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If the neuronal ensembles are turned on
at the same time,
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you experience the composite image
just as if you'd actually seen it.
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This conscious purposeful synchronization
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of different neuronal ensembles
by the prefrontal cortex
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is called mental synthesis.
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In order for mental sythesis to work,
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signals would have to arrive at both
neuronal ensembles at the same time.
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The problem is that some neurons
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are much farther away
from the prefrontal cortex than others.
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If the signals travel down both fibers
at the same rate,
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they'd arrive out of sync.
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You can't change the length
of the connections,
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but your brain,
especially as it develops in childhood,
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does have a way to change
the conduction velocity.
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Neural fibers are wrapped in a fatty
substance called myelin.
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Myelin is an insulator
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and speeds up the electrical signals
zipping down the nerve fiber.
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Some neural fibers have
as many as 100 layers of myelin.
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Others only have a few.
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And fibers with thicker layers of myelin
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can conduct signals
100 times faster or more
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than those with thinner ones.
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Some scientists now think that this
difference in myelination
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could be the key
to uniform conduction time in the brain,
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and consequently,
to our mental synthesis ability.
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A lot of this myelination
happens in childhood,
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so from an early age,
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our vibrant imaginations may have a lot
to do with building up brains
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whose carefully myelinated connections
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can craft creative symphonies
throughout our lives.
closed TED
