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Why the octopus brain is so extraordinary - Cláudio L. Guerra

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    What could octopuses possibly
    have in common with us?
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    After all, they don't have lungs, spines,
    or even a plural noun we can all agree on.
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    But what they do have is the ability
    to solve puzzles,
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    learn through observation,
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    and even use tools,
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    just like some other animals we know.
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    And what makes octopus intelligence
    so amazing
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    is that it comes
    from a biological structure
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    completely different from ours.
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    The 200 or so species of octopuses
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    are mollusks
    belonging to the order cephalopoda,
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    Greek for head-feet.
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    Those heads contain impressively
    large brains,
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    with a brain to body ratio similar
    to that of other intelligent animals,
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    and a complex nervous system with
    about as many neurons as that of a dog.
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    But instead of being
    centralized in the brain,
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    these 500 million neurons are spread out
    in a network of interconnected ganglia
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    organized into three basic structures.
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    The central brain only contains
    about 10% of the neurons,
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    while the two huge optic lobes
    contain about 30%.
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    The other 60% are in the tentacles,
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    which for humans would be like
    our arms having minds of their own.
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    This is where things
    get even more interesting.
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    Vertebrates like us have a rigid skeleton
    to support our bodies,
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    with joints that allow us to move.
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    But not all types of movement are allowed.
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    You can't bend your knee backwards,
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    or bend your forearm in the middle,
    for example.
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    Cephalopods, on the other hand,
    have no bones at all,
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    allowing them to bend their limbs
    at any point and in any direction.
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    So shaping their tentacles
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    into any one of the virtually
    limitless number of possible arrangements
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    is unlike anything we are used to.
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    Consider a simple task,
    like grabbing and eating an apple.
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    The human brain contains a neurological
    map of our body.
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    When you see the apple,
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    your brain's motor center activates
    the appropriate muscles,
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    allowing you to reach out with your arm,
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    grab it with your hand,
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    bend your elbow joint,
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    and bring it to your mouth.
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    For an octopus,
    the process is quite different.
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    Rather than a body map,
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    the cephalopod brain
    has a behavior library.
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    So when an octopus sees food,
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    its brain doesn't activate
    a specific body part,
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    but rather a behavioral response to grab.
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    As the signal travels through the network,
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    the arm neurons pick up the message
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    and jump into action
    to command the movement.
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    As soon as the arm touches the food,
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    a muscle activation wave travels
    all the way through the arm to its base,
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    while the arm sends back another wave
    from the base to the tip.
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    The signals meet halfway
    between the food and the base of the arm,
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    letting it know to bend at that spot.
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    What all this means is that each
    of an octopus's eight arms
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    can essentially think for itself.
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    This gives it amazing flexibility
    and creativity
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    when facing a new situation or problem,
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    whether its opening
    a bottle to reach food,
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    escaping through a maze,
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    moving around in a new environment,
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    changing the texture and the color
    of its skin to blend into the scenery,
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    or even mimicking other creatures
    to scare away enemies.
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    Cephalopods may have evolved
    complex brains
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    long before our vertebrate relatives.
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    And octopus intelligence isn't just useful
    for octopuses.
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    Their radically different nervous system
    and autonomously thinking appendages
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    have inspired new research
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    in developing flexible robots
    made of soft materials.
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    And studying how intelligence can arise
    along such a divergent evolutionary path
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    can help us understand more about
    intelligence and consciousness in general.
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    Who knows what other forms
    of intelligent life are possible,
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    or how they process the world around them.
Title:
Why the octopus brain is so extraordinary - Cláudio L. Guerra
Speaker:
Cláudio Guerra
Description:

View full lesson: http://ed.ted.com/lessons/why-the-octopus-brain-is-so-extraordinary-claudio-l-guerra

Octopuses have the ability to solve puzzles, learn through observation, and even use tools – just like humans. But what makes octopus intelligence so amazing is that it comes from a biological structure completely different from ours. Cláudio L. Guerra takes a look inside the amazing octopus brain.

Lesson by Cláudio L. Guerra, animation by Cinematic.
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Video Language:
English
Team:
closed TED
Project:
TED-Ed
Duration:
04:17

English subtitles

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